Enhancement of photoheterotrophic biohydrogen production at elevated temperatures by the expression of a thermophilic clostridial hydrogenase

The working temperature of a photobioreactor under sunlight can be elevated above the optimal growth temperature of a microorganism. To improve the biohydrogen productivity of photosynthetic bacteria at higher temperatures, a [FeFe]-hydrogenase gene from the thermophile Clostridium thermocellum was expressed in the mesophile Rhodopseudomonas palustris CGA009 (strain CGA-CThydA) using a log-phase expression promoter P( pckA ) to drive the expression of heterogeneous hydrogenase gene. In contrast, a mesophilic Clostridium acetobutylicum [FeFe]-hydrogenase gene was also constructed and expressed in R. palustris (strain CGA-CAhydA). Both transgenic strains were tested for cell growth, in vivo hydrogen production rate, and in vitro hydrogenase activity at elevated temperatures. Although both CGA-CThydA and CGA-CAhydA strains demonstrated enhanced growth over the vector control at temperatures above 38?°C, CGA-CThydA produced more hydrogen than the other strains. The in vitro hydrogenase activity assay, measured at 40?°C, confirmed that the activity of the CGA-CThydA hydrogenase was higher than the CGA-CAhydA hydrogenase. These results showed that the expression of a thermophilic [FeFe]-hydrogenase in R. palustris increased the growth rate and biohydrogen production at elevated temperatures. This transgenic strategy can be applied to a broad range of purple photosynthetic bacteria used to produce biohydrogen under sunlight.     

Regulation of hydrogen utilisation in Rhizobium japonicum by cyclic AMP.

Utilisation (uptake) of hydrogen gas by whole cells of Rhizobium japonicum was found to be influenced by the carbon source(s) present in the growth medium, with activity being highest in a medium containing sugars. Tricarboxylic acid cycle intermediates, such as malate, significantly reduced H2 utilisation. No reduction in the hydrogenase activity is observed when the enzyme is assayed directly by the tritium exchange method, indicating that the decrease in hydrogen uptake activity is not due to repression of hydrogenase biosynthesis. Cyclic AMP was found to alleviate the inhibition of H2 uptake by malate, and this requires new protein synthesis. Addition of chloramphenicol or rifampicin simultaneously with cyclic AMP eliminated the stimulation of H2 uptake in the malate medium. These results show that in R. japonicum cyclic AMP plays a major role in the regulation of H2 metabolism.     

Effects of anaerobic regulatory mutations and catabolite repression on regulation of hydrogen metabolism and hydrogenase isoenzyme composition in Salmonella typhimurium.

Hydrogen metabolism in Salmonella typhimurium is differentially regulated by mutations in the two anaerobic regulatory pathways, defined by the fnr (oxrA) and oxrC genes, and is controlled by catabolite repression. The synthesis of the individual hydrogenase isoenzymes is also specifically influenced by fnr and oxrC mutations and by catabolite repression in a manner entirely consistent with the proposed role for each isoenzyme in hydrogen metabolism. Synthesis of hydrogenase isoenzyme 2 was found to be fnr dependent and oxrC independent, consistent with a role in respiration-linked hydrogen uptake which was shown to be similarly regulated. Also in keeping with such a respiratory role was the finding that both hydrogen uptake and the expression of isoenzyme 2 are under catabolite repression. In contrast, formate hydrogenlyase-dependent hydrogen evolution, characteristic of fermentative growth, was reduced in oxrC strains but not in fnr strains. Hydrogenase 3 activity was similarly regulated, consistent with a role in hydrogen evolution. Unlike the expression of hydrogenases 2 and 3, hydrogenase 1 expression was both fnr and oxrC dependent. Hydrogen uptake during fermentative growth was also both fnr and oxrC dependent. This provided good evidence for a distinction between hydrogen uptake during fermentation- and respiration-dependent growth and for a hydrogen-recycling process. The pattern of anaerobic control of hydrogenase activities illustrated the functional diversity of the isoenzymes and, in addition, the physiological distinction between the two anaerobic regulatory pathways, anaerobic respiratory genes being fnr dependent and enzymes required during fermentative growth being oxrC dependent.     

The H(2) sensor of Ralstonia eutropha is a member of the subclass of regulatory [NiFe] hydrogenases

Two energy-generating hydrogenases enable the aerobic hydrogen bacterium Ralstonia eutropha (formerly Alcaligenes eutrophus) to use molecular hydrogen as the sole energy source. The complex synthesis of the nickel-iron-containing enzymes has to be efficiently regulated in response to H(2), which is available in low amounts in aerobic environments. H(2) sensing in R. eutropha is achieved by a hydrogenase-like protein which controls the hydrogenase gene expression in concert with a two-component regulatory system. In this study we show that the H(2) sensor of R. eutropha is a cytoplasmic protein. Although capable of H(2) oxidation with redox dyes as electron acceptors, the protein did not support lithoautotrophic growth in the absence of the energy-generating hydrogenases. A specifically designed overexpression system for R. eutropha provided the basis for identifying the H(2) sensor as a nickel-containing regulatory protein. The data support previous results which showed that the sensor has an active site similar to that of prototypic [NiFe] hydrogenases (A. J. Pierik, M. Schmelz, O. Lenz, B. Friedrich, and S. P. J. Albracht, FEBS Lett. 438:231-235, 1998). It is demonstrated that in addition to the enzymatic activity the regulatory function of the H(2) sensor is nickel dependent. The results suggest that H(2) sensing requires an active [NiFe] hydrogenase, leaving the question open whether only H(2) binding or subsequent H(2) oxidation and electron transfer processes are necessary for signaling. The regulatory role of the H(2)-sensing hydrogenase of R. eutropha, which has also been investigated in other hydrogen-oxidizing bacteria, is intimately correlated with a set of typical structural features. Thus, the family of H(2) sensors represents a novel subclass of [NiFe] hydrogenases denoted as the "regulatory hydrogenases."     

Regulation of hydrogen utilisation in Rhizobium japonicum by cyclic AMP

Utilisation (uptake) of hydrogen gas by whole cells of Rhizobium japonicum was found to be influenced by the carbon source(s) present in the growth medium, with activity being highest in a medium containing sugars. Tricarboxylic acid cycle intermediates, such as malate, significantly reduced H₂ utilisation. No reduction in the hydrogenase activity is observed when the enzyme is assayed directly by the tritium exchange method, indicating that the decrease in hydrogen uptake activity is not due to repression of hydrogenase biosynthesis. Cyclic AMP was found to alleviate the inhibition of H₂ uptake by malate, and this requires new protein synthesis. Addition of chloramphenicol or rifampicin simultaneously with cyclic AMP eliminated the stimulation of H₂ uptake in the malate medium. These results show that in R. japonicum cyclic AMP plays a major role in the regulation of H₂ metabolism.     

Hydrogen metabolism and energy costs of nitrogen fixation

Abstract The high energy costs of biological nitrogen fixation are partly caused by hydrogen production during the reduction of dinitrogen to ammonia. Some nitrogen-fixing organisms can recycle the evolved hydrogen via a membrane-bound uptake hydrogenase. The energetic aspects of hydrogen metabolism and nitrogen fixation are discussed.
Studies on both isolated nitrogenase proteins and nitrogen-fixing chemostat cultures show that energy limitation will result in a high hydrogen production by nitrogenase. In plant- Rhizobium symbiosis, the supply of oxygen or photosynthetate is the limiting factor for nitrogen fixation. In both cases, nitrogen fixation is energy-limited, and it is concluded that a large amount of hydrogen is produced during nitrogen fixation in these symbioses.
Hydrogen reoxidation yields less energy than the oxidation of endogenous substrates, and therefore expression of hydrogenase under oxygen-limited conditions is energetically unfavourable. Moreover, hydrogen reoxidation can never completely regain the energy invested during hydrogen production. The controversial reports of the effect of hydrogen reoxidation on the efficiency of nitrogen fixation are being discussed.
The determination of the energy costs of nitrogen fixation (expressed as the amount of ATP needed to fix 1 mol of N₂) using chemostat cultures is described. Calculations show that the nitrogenase-catalysed hydrogen production has more influence on the efficiency of nitrogen fixation than the absence or presence of a hydrogen uptake system.     

Hydrogen Oxidation by the Host-Controlled Uptake Hydrogenase Phenotype of Bradyrhizobium japonicum in Symbiosis with Soybean Host Plants

Symbioses between uptake hydrogenase host-regulated (Hup-hr) phenotypes of Bradyrhizobium japonicum and exotic, agronomically unadapted soybean germ plasm were examined for expression of uptake hydrogenase activity. Determinations for hydrogen evolution and uptake hydrogenase activity identified five plant introduction (PI) lines which formed hydrogen-oxidizing symbioses with strains USDA 61 and PA3 6c. Hup-hr strains belonging to serogroup 94 expressed uptake hydrogenase activity in symbioses with PI 181696 and PI 219655 at rates sufficient to prevent hydrogen from escaping the nodules. The identification of soybean germ plasm forming hydrogen-oxidizing symbioses with Hup-hr bradyrhizobia potentially has implications for enhancing nitrogen fixation efficiency in soybean production.     

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.     

<Emphasis Type="Italic">Escherichia coli</Emphasis> hydrogenase 3 is a reversible enzyme possessing hydrogen uptake and synthesis activities

In the past, it has been difficult to discriminate between hydrogen synthesis and uptake for the three active hydrogenases in Escherichia coli (hydrogenase 1, 2, and 3); however, by combining isogenic deletion mutations from the Keio collection, we were able to see the role of hydrogenase 3. In a cell that lacks hydrogen uptake via hydrogenase 1 (hyaB) and via hydrogenase 2 (hybC), inactivation of hydrogenase 3 (hycE) decreased hydrogen uptake. Similarly, inactivation of the formate hydrogen lyase complex, which produces hydrogen from formate (fhlA) in the hyaB hybC background, also decreased hydrogen uptake; hence, hydrogenase 3 has significant hydrogen uptake activity. Moreover, hydrogen uptake could be restored in the hyaB hybC hycE and hyaB hybC fhlA mutants by expressing hycE and fhlA, respectively, from a plasmid. The hydrogen uptake results were corroborated using two independent methods (both filter plate assays and a gas-chromatography-based hydrogen uptake assay). A 30-fold increase in the forward reaction, hydrogen formation by hydrogenase 3, was also detected for the strain containing active hydrogenase 3 activity but no hydrogenase 1 or 2 activity relative to the strain lacking all three hydrogenases. These results indicate clearly that hydrogenase 3 is a reversible hydrogenase.     

Differential expression of hydrogenase isoenzymes in Escherichia coli K-12: evidence for a third isoenzyme.

The cellular contents of the nickel-containing, membrane-bound hydrogenase isoenzymes 1 and 2 (hydrogenases 1 and 2) were analyzed by crossed immunoelectrophoresis. Their expression was differentially influenced by nutritional and genetic factors. Hydrogenase 2 content was enhanced after growth with either hydrogen and fumarate or glycerol and fumarate and correlated reasonably with cellular hydrogen uptake capacity. Hydrogenase 1 content was negligible under the above conditions but was enhanced by exogenous formate. Its expression was greatly reduced in a pfl mutant, which is unable to synthesise formate, but was restored to normal levels when the growth medium included formate. A mutation in the anaerobic regulatory gene, fnr, led to low overall hydrogenase activity and greatly reduced levels of both isoenzymes and abolished the formate enhancement of hydrogenase 1 content. Formate hydrogenlyase activity was similarly reduced in the fnr strain but, in contrast, was restored, as was overall hydrogenase activity, to normal levels by growth in the presence of formate. Low H2 uptake activity was found for the fnr strain under all growth conditions examined. Hydrogenase 1 content, therefore, does not correlate with formate hydrogenlyase activity and its role is unclear. A third hydrogenase isoenzyme, immunologically distinct from hydrogenases 1 and 2, whose expression is enhanced by formate, is present and forms part of the formate hydrogenlyase. We suggest that the effect of the fnr gene product on formate hydrogenlyase expression is mediated via internal formate.     

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.     

Production of hydrogen gas from light and the inorganic electron donor thiosulfate by Rhodopseudomonas palustris

A challenge for photobiological production of hydrogen gas (H(2)) as a potential biofuel is to find suitable electron-donating feedstocks. Here, we examined the inorganic compound thiosulfate as a possible electron donor for nitrogenase-catalyzed H(2) production by the purple nonsulfur phototrophic bacterium (PNSB) Rhodopseudomonas palustris. Thiosulfate is an intermediate of microbial sulfur metabolism in nature and is also generated in industrial processes. We found that R. palustris grew photoautotrophically with thiosulfate and bicarbonate and produced H(2) when nitrogen gas was the sole nitrogen source (nitrogen-fixing conditions). In addition, illuminated nongrowing R. palustris cells converted about 80% of available electrons from thiosulfate to H(2). H(2) production with acetate and succinate as electron donors was less efficient (40 to 60%), partly because nongrowing cells excreted the intermediary metabolite α-ketoglutarate into the culture medium. The fixABCX operon (RPA4602 to RPA4605) encoding a predicted electron-transfer complex is necessary for growth using thiosulfate under nitrogen-fixing conditions and may serve as a point of engineering to control rates of H(2) production. The possibility to use thiosulfate expands the range of electron-donating compounds for H(2) production by PNSBs beyond biomass-based electron donors.     

Use of hupS::lacZ gene fusion to study regulation of hydrogenase expression in Rhodobacter capsulatus: stimulation by H2.

The Escherichia coli beta-galactosidase enzyme was used as a reporter molecule for genetic fusions in Rhodobacter capsulatus. DNA fragments that were from the upstream region of the hydrogenase structural operon hupSLM and contained 5' hupS sequences were fused in frame to a promoterless lacZ gene, yielding fusion proteins comprising the putative signal sequence and the first 22 amino acids of the HupS protein joined to the eight amino acid of beta-galactosidase. We demonstrate the usefulness of the hupS::lacZ fusion in monitoring regulation of hydrogenase gene expression. The activities of plasmid-determined beta-galactosidase and chromosome-encoded hydrogenase changed in parallel in response to various growth conditions (light or dark, aerobiosis or anaerobiosis, and presence or absence of ammonia or of H2), showing that changes in hydrogenase activity were due to changes in enzyme synthesis. Molecular hydrogen stimulated hydrogenase synthesis in dark, aerobic cultures and in illuminated, anaerobic cultures. Analysis of hupS::lacZ expression in various mutants indicated that neither the hydrogenase structural genes nor NifR4 (sigma 54) was essential for hydrogen regulation of hydrogenase synthesis.     

Evaluation and improvement of the energy efficiency of nitrogen fixation in Lotus corniculatus nodules induced by Rhizobium loti strains indigenous to Uruguay

In order to evaluate energy efficiency of nitrogen fixation by the Lotus corniculatus/Rhizobium loti symbiosis, Uruguayan R. loti strains were tested for hydrogen-uptake (Hup) status. Nodules induced in L. corniculatus by all eight R. loti strains tested evolved high amounts of hydrogen (2.0–8.7 mol H2/h.g nodule fresh weight). This production of hydrogen corresponds to 38–69% of total nitrogenase activity estimated as acetylene reduction, suggesting that hydrogen is not recycled within these nodules. This was confirmed by the lack of hydrogenase activity in bacteroid suspensions. Additionally, no hybridization signals were observed in total DNA restriction digests from these strains when a DNA fragment containing part of hydrogenase structural genes from Rhizobium leguminosarum bv. viciae was used as probe. Cosmid pHU52, containing the complete gene cluster required for hydrogen oxidation in Bradyrhizobium japonicum, was introduced into two R. loti strains. Transconjugants from only one of the strains were able to express hydrogenase activity in vegetative cells incubated under the derepression conditions described for B. japonicum. Bacteroids induced by both transconjugant strains in L. corniculatus and Lotus tenuis expressed hydrogenase activity in nodules. The level of hydrogenase activity induced in L. tenuis nodules was two-fold higher than those induced in L. corniculatus. This implies the existence of a strong host effect on hydrogenase expression in this symbiotic system.