Identification of a membrane-bound hydrogenase of Desulfovibrio vulgaris (Hildenborough)

Two hydrogenase activities from Desulfovibrio vulgaris (Hildenborough) could be distinguished immunologically and biochemically. The first activity, described as hydrogenase I, corresponded to the soluble enzyme located in the periplasmic space of D. vulgaris. Hydrogenase I had a high specific activity and was sensitive to inhibition by CO. The second activity, hydrogenase II, was located in the membrane fraction, had a lower specific activity and was not affected by CO. The enzymes exhibited different electrophoretic mobilities in polyacrylamide gels, and reacted differently when exposed to proteases. Antibodies raised against purified periplasmic hydrogenase of D. vulgaris reacted with hydrogenase I, but not with hydrogenase II.     

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.     

2,4,6-Trinitrotoluene Reduction by an Fe-Only Hydrogenase in Clostridium acetobutylicum

The role of hydrogenase on the reduction of 2,4,6-trinitrotoluene (TNT) in Clostridium acetobutylicum was evaluated. An Fe-only hydrogenase was isolated and identified by using TNT reduction activity as the selection basis. The formation of hydroxylamino intermediates by the purified enzyme corresponded to expected products for this reaction, and saturation kinetics were determined with a K_m of 152 μM. Comparisons between the wild type and a mutant strain lacking the region encoding an alternative Fe-Ni hydrogenase determined that Fe-Ni hydrogenase activity did not significantly contribute to TNT reduction. Hydrogenase expression levels were altered in various strains, allowing study of the role of the enzyme in TNT reduction rates. The level of hydrogenase activity in a cell system correlated (R² = 0.89) with the organism's ability to reduce TNT. A strain that overexpressed the hydrogenase activity resulted in maintained TNT reduction during late growth phases, which it is not typically observed in wild type strains. Strains exhibiting underexpression of hydrogenase produced slower TNT rates of reduction correlating with the determined level of expression. The isolated Fe-only hydrogenase is the primary catalyst for reducing TNT nitro substituents to the corresponding hydroxylamines in C. acetobutylicum in whole-cell systems. A mechanism for the reaction is proposed. Due to the prevalence of hydrogenase in soil microbes, this research may enhance the understanding of nitroaromatic compound transformation by common microbial communities.     

Acetylene, Not Ethylene, Inactivates the Uptake Hydrogenase of Actinorhizal Nodules during Acetylene Reduction Assays

Acetylene reduction assays were shown to inactivate uptake hydrogenase activity to different extents in one Casuarina and two Alnus symbioses. Inactivation was found to be caused by C₂H₂ and not by C₂H₄. Acetylene completely inactivated the hydrogenase activity of intact root systems of Alnus incana inoculated with Frankia strain Avcl1 in 90 minutes, as shown by a drop in the relative efficiency of nitrogenase from 1.0 to 0.73. The hydrogenase of Frankia preparations (containing vesicles) and of cell-free extracts (not containing vesicles) from the same symbiosis was much more susceptible to acetylene inactivation. Cell-free extracts lost all hydrogenase activity after 5 minutes of exposure to acetylene. The hydrogenase activity of intact root systems of Casuarina obesa was less sensitive to acetylene than that of root systems of A. incana, since the relative efficiency of nitrogenase changed only from 1.0 to 0.95 over 90 minutes. Frankia preparations and cell-free extracts of C. obesa still retained hydrogenase activity after a 10 minute-exposure to acetylene.     

Activities, occurrence, and localization of hydrogenase in free-living and symbiotic frankia

Symbiotic and free-living Frankia were investigated for correlation between hydrogenase activities (in vivo/in vitro assays) and for occurrence and localization of hydrogenase protein by Western blots and immuno-gold localization, respectively. Freshly prepared nodule homogenates from the symbiosis between Alnus incana and a local source of Frankia did not show any detectable in vivo or in vitro hydrogenase uptake activity, as also has been shown earlier. However, a free-living Frankia strain originally isolated from these nodules clearly showed both in vivo and in vitro hydrogenase activity, with the latter being approximately four times higher. Frankia strain Cpl1 showed hydrogen uptake activity both in symbiosis with Alnus incana and in a free-living state. Western blots on the different combinations of host plants and Frankia strains used in the present study revealed that all the Frankia sources contained a hydrogenase protein, even the local source where no in vivo or in vitro activity could be measured. The 72 kilodalton protein found in the symbiotic Frankia as well as in the free-living Frankia strains were immunologically related to the large subunit of a dimeric hydrogenase purified from Alcaligenes latus. Recognitions to polypeptides with molecular masses of about 41 and 19.5 kilodaltons were also observed in Frankia strain UGL011101 and in the local source of Frankia, respectively. Immunogold localization of the protein demonstrated that in both the symbiotic state and the free-living nitrogen-fixing Frankia, the protein is located in vesicles and in hyphae. The inability to measure any uptake hydrogenase activity is therefore not due to the absence of hydrogenase enzyme. However, the possibility of an inactive hydrogenase enzyme cannot be ruled out.     

Reinvestigation of the steady-state kinetics and physiological function of the soluble NiFe-hydrogenase I of Pyrococcus furiosus

Pyrococcus furiosus has two types of NiFe-hydrogenases: a heterotetrameric soluble hydrogenase and a multimeric transmembrane hydrogenase. Originally, the soluble hydrogenase was proposed to be a new type of H₂ evolution hydrogenase, because, in contrast to all of the then known NiFe-hydrogenases, the hydrogen production activity at 80°C was found to be higher than the hydrogen consumption activity and CO inhibition appeared to be absent. NADPH was proposed to be the electron donor. Later, it was found that the membrane-bound hydrogenase exhibits very high hydrogen production activity sufficient to explain cellular H₂ production levels, and this seems to eliminate the need for a soluble hydrogen production activity and therefore leave the soluble hydrogenase without a physiological function. Therefore, the steady-state kinetics of the soluble hydrogenase were reinvestigated. In contrast to previous reports, a low K_m for H₂ (~20 μM) was found, which suggests a relatively high affinity for hydrogen. Also, the hydrogen consumption activity was 1 order of magnitude higher than the hydrogen production activity, and CO inhibition was significant (50% inhibition with 20 μM dissolved CO). Since the K_m for NADP⁺ is ~37 μM, we concluded that the soluble hydrogenase from P. furiosus is likely to function in the regeneration of NADPH and thus reuses the hydrogen produced by the membrane-bound hydrogenase in proton respiration.     

Influence of the Bradyrhizobium japonicum Hydrogenase on the Growth of Glycine and Vigna Species

The effect of the Bradyrhizobium japonicum hydrogenase on nitrogen fixation was evaluated by comparing the growth of Vigna and Glycine species inoculated with a Hup mutant and its Hup⁺ revertant. In all experiments, the growth of plants inoculated with the strain without hydrogenase was at least equal to the growth of the strain with hydrogenase. For Glycine usuriensis and Glycine max cv. Hodgson in liquid culture, the growth was higher with the Hup⁻ strain. It is possible that reduced rates of nitrogen fixation in the presence of hydrogenase are due to O₂ depletion caused by the hydrogen oxidizing, since the oxygen pressure in the air appears to be a limiting factor of symbiotic nitrogen fixation in the soybean.     

Intracellular Location and O2 Sensitivity of Uptake Hydrogenase in Azospirillum spp

Uptake hydrogenase activity of Azospirillum brasilense in vitro (cell-free extract) was very much more sensitive to O₂ than was that of A. amazonense, and the O₂ pressure optima for uptake hydrogenase activities were 0.01 and 0.4 to 3 kPa for A. brasilense and A. amazonense, respectively. The addition of superoxide dismutase did not increase uptake hydrogenase activity of A. brasilense either in vivo or in vitro. The O₂ uptake rates of A. brasilense and A. amazonense were nearly the same. Inhibition of A. brasilense O₂-dependent uptake hydrogenase activity by O₂ was highly reversible under the conditions tested. O₂ also markedly inhibited in vitro methylene blue-dependent uptake hydrogenase activity of A. brasilense, and this inhibition was highly reversible. It is concluded that the difference in O₂ tolerance of the uptake hydrogenases is not due to a difference in respiratory protection in the two species and may be due to inherent differences in the two enzymes. For the three species, A. brasilense, A. amazonense, and A. lipoferum, almost all the recovered methylene blue-dependent uptake hydrogenase activity was associated with the membrane fraction.     

The hupC gene product is a component of the electron transport system for hydrogen oxidation in Pseudomonas hydrogenovora

The hydrogenase gene cluster containing nine genes (hupSLCDFGHIJ) was identified by sequencing of an 8.8-kb DNA region from Pseudomonas hydrogenovora. To investigate the function of the hupC gene product, we isolated a hupC-null mutant (HID3) of P. hydrogenovora by introducing an in-frame deletion into the hupC. The mutant, HID3, could not grow autotrophically but retained half the level of hydrogenase activity of the wild-type strain. Results of the oxygen consumption test and Western blot analysis revealed that the hupC gene product is a b-type cytochrome but not involved in the hydrogenase maturation process.     

Interaction of HydSL hydrogenase from the purple sulfur bacterium Thiocapsa roseopersicina BBS with methyl viologen and positively charged polypeptides

The effect of polypeptides having different charge on the activity of Thiocapsa roseopersicina HydSL hydrogenase was studied. Strong inhibition was shown for poly-L-lysine bearing positive charge. The inhibition was reversible and competitive to methyl viologen, an electron acceptor, in the reaction of hydrogen oxidation catalyzed by the hydrogenase. Peptides carrying less positive charge had weaker inhibiting effect, while neutral and negatively charged peptides did not inhibit the hydrogenase. Molecular docking of poly-L-lysine to T. roseopersicina hydrogenase showed strong affinity of this polypeptide to the acceptor-binding site of the enzyme. The calculated binding constant is close to the experimentally measured value (K _i = 2.1 μM).     

The purification of hydrogenase II (uptake hydrogenase) from the anaerobic N2-fixing bacterium Clostridium pasteurianum

The H₂ uptake activity (units/mg protein) of Clostridium pasteurianum cells with methylene blue as the electron acceptor increases with cell density independent of the growth conditions. The H₂ evolution activity (units/mg protein) of the same cells with reduced methyl viologen as the electron donor remains fairly constant under all growth conditions tested. Cells grown under N₂-fixing conditions have the highest H₂ uptake activity and were used for the purification of hydrogenase II (uptake hydrogenase). Attempts to separate hydrogenase II from hydrogenase I (bidirectional hydrogenase) by a previously published method were unreliable. We report here a new large-scale purification procedure which employs a rapid membrane filtration system to fractionate cell-free extracts. Hydrogenases I and II were easily filtered into the low-molecular-weight fraction (M_r less than 100 000), and from this, hydrogenase II was further purified to a homogeneous state. Hydrogenase II is a monomeric iron-sulfur protein of molecular weight 53 000 containing eight iron atoms and eight acid-labile sulfur atoms per molecule. Hydrogenase II catalyzes both H₂ oxidation and H₂ evolution at rates of 3000 and 5.9 μmol H₂ consumed or evolved/min per mg protein, respectively. The purification procedure for hydrogenase II using the filtration system described greatly facilitates the large-scale purification of hydrogenase I and other enzymes from cell-free extracts of C. pasteurianum.     

Variation in nitrogenase and hydrogenase activity of alaska pea root nodules

Hydrogenase activity of root nodules in the symbiotic association between Pisum sativum L. and Rhizobium leguminosarum was determined by incubating unexcised nodules with tritiated H₂ and measuring tissue HTO. Hydrogenase activity saturated at 0.50 millimolar H₂ and was not inhibited by the presence of 0.10 atmosphere C₂H₂, which prevented H₂ evolution from nitrogenase. Total H₂ production from nitogenase was estimated as net H₂ evolution in air plus H₂ exchange in 0.10 atmosphere C₂H₂. Although such an estimate of nitrogenase function may not be quantitatively exact, due to uncertain relationships between H₂ exchange and H₂ uptake activity of hydrogenase, differences observed in H₂ exchange under various conditions represent an indication of changes in hydrogenase activity. Hydrogenase activity was lower in associations grown under higher photosynthetic photon flux densities and decreased relative to total H₂ production by nitrogenase. Total H₂ production and hydrogenase activity were maximum 28 days after planting. Thereafter, hydrogenase activity and H₂ production declined, but the potential proportion of nitrogenase-produced H₂ recovered by the uptake hydrogenase system increased. Of five R. leguminosarum strains tested two possessed hydrogenase activity. Strains which had the potential to reassimilate H₂ had significantly higher rates of N₂ reduction than those which did not exhibit hydrogenase activity.     

H2-Uptake and evolution in the unicellular cyanobacterium Chroococcidiopsis thermalis CALU 758

The unicellular cyanobacterium Chroococcidiopsis thermalis CALU 758 growing photoautotrophically synthesised a hydrogenase which catalysed an in vivo H₂ uptake in the oxyhydrogen reaction at a significant rate and showed only low level of in vitro MV-dependent H₂ evolution. The in vitro hydrogenase activity was not induced under microaerobic or nitrate-limiting conditions. Some correlation observed between the two activities indicated that the same enzyme may be involved in both H₂ uptake and H₂ evolution. Heterologous Southern hybridisations, using cyanobacterial hup and hox DNA fragments as probes, showed the presence of sequences similar to hox (encoding for a bidirectional hydrogenase) in C. thermalis CALU 758 with no indication for the presence of any sequences corresponding to an uptake hydrogenase. Further molecular experiments, using specific primers directed against different conserved regions of the large subunit (hoxH) of the bidirectional hydrogenase confirmed the presence of corresponding sequences in C. thermalis CALU 758. Low-stringency Southern hybridisations detected only one copy of hoxH within the genome of C. thermalis CALU 758.     

Hydrogen production by Escherichia coli containing a cloned hydrogenase gene from Citrobacter freundii

Two hydrogenase genes of Citrobacter freundii complementing different Escherichia coli hyd mutations were cloned on the multicopy-plasmid pBR322. Recombinant plasmids pCBH2 and pCFH1 were obtained. Since hydrogenase activities of E. coli transformant HK-8 (pCBH2) and HK-7 (pCFH1) were much the same as E. coli C600 (wild type cells), the reduction in DNA size of recombinant plasmid pCBH2 (10.7 kb) was investigated. Reduced recombinant plasmids pCBH4 (6.2 kb) and pCBH6 (5.7 kb) were obtained, and a hydrogenase gene was found to be located on the 2.35 kb fragment between AvaI and EcoRI sites. Hydrogenase activity and hydrogen-evolving activity of E. coli HK-8 (pCBH4 or pCBH6) from sodium formate, sodium pyruvate or glucose were approximately 2-fold higher than those of E. coli C600 (wild type cells).On the other hand, a reduced recombinant plasmid pCBH10 (6.0 kb), which contained the adjacent DNA fragment (2.15 kb) to a hydrogenase gene, was obtained. Hydrogenase activity of E. coli C600 harboring pCBH10 was half that of E. coli C600. From these results we estimate that in plasmid pCBH2, the repressor gene suppressing the synthesis of hydrogenase might have been cloned together with a hydrogenase gene.     

Activation and de novo synthesis of hydrogenase in chlamydomonas

Two distinct processes are involved in the formation of active hydrogenase during anaerobic adaptation of Chlamydomonas reinhardtii cells. In the first 30 minutes of anaerobiosis, nearly all of the hydrogenase activity can be attributed to activation of a constituitive polypeptide precursor, based on the insensitivity of the process to treatment with cycloheximide (15 micrograms per milliliter). This concentration of cycloheximide inhibits protein synthesis by greater than 98%. After the initial activation period, de novo protein synthesis plays a critical role in the adaptation process since cycloheximide inhibits the expression of hydrogense in maximally adapted cells by 70%. Chloramphenicol (500 micrograms per milliliter) has a much lesser effect on the adaptation process.

Incubation of cell-free extracts under anaerobic conditions in the presence of dithionite, dithiothreitol, NADH, NADP, ferredoxin, ATP, Mg²⁺, Ca²⁺, and iron does not lead to active hydrogenase formation. Futhermore, in vivo reactivation of oxygen-inactivated hydrogenase does not appear to take place.

The adaptation process is very sensitive to the availability of iron. Iron-deficient cultures lose the ability to form active hydrogenase before growth, photosynthesis, and respiration are significantly affected. Preincubation of iron-deficient cells with iron 2 hours prior to the adaptation period fully restores the capacity of the cells to synthesize functional hydrogenase.

     

Purification and properties of the H2-oxidizing (uptake) hydrogenase of the N2-fixing anaerobe Clostridium pasteurianum W5

Clostridium pasteurianum has two distinct hydrogenases, the bidirectional hydrogenase and the H₂-oxidizing (uptake) hydrogenase. The H₂-oxidizing hydrogenase has been purified (up to 970-fold) to a specific activity of 17,600 μmol H₂ oxidized/min·mg protein (5 mM methylene blue) or 3.5 μmol H₂ produced/min·mg protein (1 mM methyl viologen). The uptake hydrogenase has a M_r of 53,000 (one polypeptide chain). Depending upon how protein was measured, the Fe and S⁼ contents (gatom/mol) were 4.7 and 5.2 (by the dye-binding assay) or 7.2 and 8.0 (by the Lowry method). Both reduced and oxidized forms of the enzyme gave electron paramagnetic resonance signals. The activation energy for H₂-production and H₂-oxidation by the uptake hydrogenase was 59.1 and 31.2 kJ/mol, respectively. In the exponential phase of growth, the ratio of uptake hydrogenase/bidirectional hydrogenase in NH₃-grown cells was much lower than that in N₂-fixing cells.     

Dual organism design cycle reveals small subunit substitutions that improve [NiFe] hydrogenase hydrogen evolution

Background

Photosynthetic microorganisms that directly channel solar energy to the production of molecular hydrogen are a potential future biofuel system. Building such a system requires installation of a hydrogenase in the photosynthetic organism that is both tolerant to oxygen and capable of hydrogen production. Toward this end, we have identified the [NiFe] hydrogenase from the marine bacterium Alteromonas macleodii “Deep ecotype” that is able to be heterologously expressed in cyanobacteria and has tolerance to partial oxygen. The A. macleodii enzyme shares sequence similarity with the uptake hydrogenases that favor hydrogen uptake activity over hydrogen evolution. To improve hydrogen evolution from the A. macleodii hydrogenase, we examined the three Fe-S clusters found in the small subunit of many [NiFe] uptake hydrogenases that presumably act as a molecular wire to guide electrons to or from the active site of the enzyme. Studies by others altering the medial cluster of a Desulfovibrio fructosovorans hydrogenase from 3Fe-4S to 4Fe-4S resulted in two-fold improved hydrogen evolution activity.

Results

We adopted a strategy of screening for improved hydrogenase constructs using an Escherichia coli expression system before testing in slower growing cyanobacteria. From the A. macleodii enzyme, we created a mutation in the gene encoding the hydrogenase small subunit that in other systems is known to convert the 3Fe-4S medial cluster to 4Fe-4S. The medial cluster substitution did not improve the hydrogen evolution activity of our hydrogenase. However, modifying both the medial cluster and the ligation of the distal Fe-S cluster improved in vitro hydrogen evolution activity relative to the wild type hydrogenase by three- to four-fold. Other properties of the enzyme including thermostability and tolerance to partial oxygen did not appear to be affected by the substitutions.

Conclusions

Our results show that substitution of amino acids altering the ligation of Fe-S clusters in the A. macleodii [NiFe] uptake hydrogenase resulted in increased hydrogen evolution activity. This activity can be recapitulated in multiple host systems and with purified protein. These results validate the approach of using an E. coli-cyanobacteria shuttle system for enzyme expression and improvement.