Hydrogenase, nitrogenase, and hydrogen metabolism in the photosynthetic bacteria

Optimal iron concentrations for growth-associated polyhydroxyalkanoate biosynthesis in the marine photosynthetic purple bacterium Rhodovulum sulfidophilum under photoheterotrophic condition

Polyhydroxyalkanoates (PHAs) are a group of natural biopolyesters that resemble petroleum-derived plastics in terms of physical properties but are less harmful biologically to the environment and humans. Most of the current PHA producers are heterotrophs, which require expensive feeding materials and thus contribute to the high price of PHAs. Marine photosynthetic bacteria are promising alternative microbial cell factories for cost-effective, carbon neutral and sustainable production of PHAs. In this study, Rhodovulum sulfidophilum, a marine photosynthetic purple nonsulfur bacterium with a high metabolic versatility, was evaluated for cell growth and PHA production under the influence of various media components found in previous studies. We evaluated iron, using ferric citrate, as another essential factor for cell growth and efficient PHA production and confirmed that PHA production in R. sulfidophilum was growth-associated under microaerobic and photoheterotrophic conditions. In fact, a subtle amount of iron (1 to 2 μM) was sufficient to promote rapid cell growth and biomass accumulation, as well as a high PHA volumetric productivity during the logarithmic phase. However, an excess amount of iron did not enhance the growth rate or PHA productivity. Thus, we successfully confirmed that an optimum concentration of iron, an essential nutrient, promotes cell growth in R. sulfidophilum and also enhances PHA utilization.

H2 production in Rhodopseudomonas palustris as a way to cope with high light intensities

The ability of coping with the damaging effects of high light intensity represents an essential issue when purple non-sulfur bacteria (PNSB) are grown under direct sunlight for photobiological hydrogen production. This study was aimed at investigating whether H2 photo-evolution could represent, for Rhodopseudomonas palustris 42OL, a safety valve to dissipate an excess of reducing power generated under high light intensities. The physiological status of this strain was assessed under anaerobic (AnG) and aerobic (AG) growing conditions and under H2-producing (HP) conditions at low and high light intensities. The results obtained clearly showed that Fv/Fm ratio was significantly affected by the light intensity under which R. palustris 42OL cells were grown, under either AnG or AG conditions, while, under HP, it constantly remained at its highest value. The increase in light intensity significantly increased the H2 production rate, which showed a positive correlation with the maximum electron transfer rate (rETRmax). These findings are important for optimization of hydrogen production by PNSB under solar light.

Implementation of photobiological H2 production: the O 2 sensitivity of hydrogenases

The search for the ultimate carbon-free fuel has intensified in recent years, with a major focus on photoproduction of H2. Biological sources of H2 include oxygenic photosynthetic green algae and cyanobacteria, both of which contain hydrogenase enzymes. Although algal and cyanobacterial hydrogenases perform the same enzymatic reaction through metallo-clusters, their hydrogenases have evolved separately, are expressed differently (transcription of algal hydrogenases is anaerobically induced, while bacterial hydrogenases are constitutively expressed), and display different sensitivity to O2 inactivation. Among various physiological factors, the sensitivity of hydrogenases to O2 has been one of the major factors preventing implementation of biological systems for commercial production of renewable H2. This review addresses recent strategies aimed at engineering increased O2 tolerance into hydrogenases (as of now mainly unsuccessful), as well as towards the development of methods to bypass the O2 sensitivity of hydrogenases (successful but still yielding low solar conversion efficiencies). The author concludes with a description of current approaches from various laboratories to incorporate multiple genetic traits into either algae or cyanobacteria to jointly address limiting factors other than the hydrogenase O2 sensitivity and achieve more sustained H2 photoproduction activity.

Learning from photosynthesis: how to use solar energy to make fuels

This short review describes how the basic reactions of photosynthesis can be broken down into four distinct steps. The current understanding of the molecular mechanisms of these steps, within light-harvesting complexes and reaction centres, in this process is discussed as a framework for the construction of artificial systems capable of using solar energy to make fuels.

Thermotolerant hydrogenases: biological diversity, properties, and biotechnological applications

Hydrogenases are metalloproteins that catalyze the oxidation and reduction of molecular hydrogen and play a crucial role in many microbial metabolic processes. A subset of hydrogenases capable of functioning at temperatures from 50 to 125 degrees C is found in thermophilic microorganisms. Most known thermotolerant hydrogenases contain a [NiFe] active site and are either bidirectional or uptake type. Although no exhaustive survey has been done of the ecological diversity of thermophilic hydrogen-reducing or oxidizing bacteria, they appear to exist in virtually every thermophilic environment examined to date. Thermotolerant hydrogenases share many similarities with their mesophilic counterparts, but they have several features in addition to thermotolerance that make them especially well suited for biotechnological applications. Ongoing research is focused on potential applications of thermotolerant H2 ases in biosynthesis, H2 production, bioremediation, and biosensors.

Development of a solar-powered microbial fuel cell

AIMS

To understand factors that impact solar-powered electricity generation by Rhodobacter sphaeroides in a single-chamber microbial fuel cell (MFC).

METHODS AND RESULTS

The MFC used submerged platinum-coated carbon paper anodes and cathodes of the same material, in contact with atmospheric oxygen. Power was measured by monitoring voltage drop across an external resistance. Biohydrogen production and in situ hydrogen oxidation were identified as the main mechanisms for electron transfer to the MFC circuit. The nitrogen source affected MFC performance, with glutamate and nitrate-enhancing power production over ammonium.

CONCLUSIONS

Power generation depended on the nature of the nitrogen source and on the availability of light. With light, the maximum point power density was 790 mW m(-2) (2.9 W m(-3)). In the dark, power output was less than 0.5 mW m(-2) (0.008 W m(-3)). Also, sustainable electrochemical activity was possible in cultures that did not receive a nitrogen source.

SIGNIFICANCE AND IMPACT OF THE STUDY

We show conditions at which solar energy can serve as an alternative energy source for MFC operation. Power densities obtained with these one-chamber solar-driven MFC were comparable with densities reported in nonphotosynthetic MFC and sustainable for longer times than with previous work on two-chamber systems using photosynthetic bacteria.

Hydrogenases and H(+)-reduction in primary energy conservation

Hydrogenases are metalloenzymes subdivided into two classes that contain iron-sulfur clusters and catalyze the reversible oxidation of hydrogen gas (H(2)[Symbol: see text]left arrow over right arrow[Symbol: see text]2H(+)[Symbol: see text]+[Symbol: see text]2e(-)). Two metal atoms are present at their active center: either a Ni and an Fe atom in the [NiFe]hydrogenases, or two Fe atoms in the [FeFe]hydrogenases. They are phylogenetically distinct classes of proteins. The catalytic core of [NiFe]hydrogenases is a heterodimeric protein associated with additional subunits in many of these enzymes. The catalytic core of [FeFe]hydrogenases is a domain of about 350 residues that accommodates the active site (H cluster). Many [FeFe]hydrogenases are monomeric but possess additional domains that contain redox centers, mostly Fe-S clusters. A third class of hydrogenase, characterized by a specific iron-containing cofactor and by the absence of Fe-S cluster, is found in some methanogenic archaea; this Hmd hydrogenase has catalytic properties different from those of [NiFe]- and [FeFe]hydrogenases. The [NiFe]hydrogenases can be subdivided into four subgroups: (1) the H(2) uptake [NiFe]hydrogenases (group 1); (2) the cyanobacterial uptake hydrogenases and the cytoplasmic H(2) sensors (group 2); (3) the bidirectional cytoplasmic hydrogenases able to bind soluble cofactors (group 3); and (4) the membrane-associated, energy-converting, H(2) evolving hydrogenases (group 4). Unlike the [NiFe]hydrogenases, the [FeFe]hydrogenases form a homogeneous group and are primarily involved in H(2) evolution. This review recapitulates the classification of hydrogenases based on phylogenetic analysis and the correlation with hydrogenase function of the different phylogenetic groupings, discusses the possible role of the [FeFe]hydrogenases in the genesis of the eukaryotic cell, and emphasizes the structural and functional relationships of hydrogenase subunits with those of complex I of the respiratory electron transport chain.

Spectral signatures of photosynthesis. I. Review of Earth organisms

Why do plants reflect in the green and have a "red edge" in the red, and should extrasolar photosynthesis be the same? We provide (1) a brief review of how photosynthesis works, (2) an overview of the diversity of photosynthetic organisms, their light harvesting systems, and environmental ranges, (3) a synthesis of photosynthetic surface spectral signatures, and (4) evolutionary rationales for photosynthetic surface reflectance spectra with regard to utilization of photon energy and the planetary light environment. We found the "near-infrared (NIR) end" of the red edge to trend from blue-shifted to reddest for (in order) snow algae, temperate algae, lichens, mosses, aquatic plants, and finally terrestrial vascular plants. The red edge is weak or sloping in lichens. Purple bacteria exhibit possibly a sloping edge in the NIR. More studies are needed on pigment-protein complexes, membrane composition, and measurements of bacteria before firm conclusions can be drawn about the role of the NIR reflectance. Pigment absorbance features are strongly correlated with features of atmospheric spectral transmittance: P680 in Photosystem II with the peak surface incident photon flux density at approximately 685 nm, just before an oxygen band at 687.5 nm; the NIR end of the red edge with water absorbance bands and the oxygen A-band at 761 nm; and bacteriochlorophyll reaction center wavelengths with local maxima in atmospheric and water transmittance spectra. Given the surface incident photon flux density spectrum and resonance transfer in light harvesting, we propose some rules with regard to where photosynthetic pigments will peak in absorbance: (1) the wavelength of peak incident photon flux; (2) the longest available wavelength for core antenna or reaction center pigments; and (3) the shortest wavelengths within an atmospheric window for accessory pigments. That plants absorb less green light may not be an inefficient legacy of evolutionary history, but may actually satisfy the above criteria.

Metabolically engineered Rhodobacter sphaeroides RV strains for improved biohydrogen photoproduction combined with disposal of food wastes

Three differently metabolically engineered strains, 2 single PHA- and Hup- mutants and one double PHA-/Hup- mutant, of the purple nonsulfur photosynthetic bacterium Rhodobacter sphaeroides RV, were constructed to improve a light-driven biohydrogen production process combined with the disposal of solid food wastes. These phenotypes were designed to abolish, singly or in combination, the competition of H2 photoproduction with polyhydroxyalkanoate (PHA) accumulation by inactivating PHA synthase activity, and with H2 recycling by abolishing the uptake hydrogenase enzyme. The performance of these mutants was compared with that of the wild-type strain in laboratory tests carried out in continuously fed photobioreactors using as substrates both synthetic media containing lactic acid and media from the acidogenic fermentation of actual fruit and vegetable wastes, containing mainly lactic acid, smaller amounts of acetic acia, and traces of higher volatile acids. With the lactic acid-based synthetic medium, the single Hup- and the double PHA-/Hup- mutants, but not the single PHA- mutant, exhibited increased rates of H2 photoproduction, about one third higher than that of the wild-type strain. With the food-waste-derived growth medium, only the single Hup- mutant showed higher rates of H2 production, but all 3 mutants sustained a longer-term H2 photoproduction phase than the wild-type strain, with the double mutant exhibiting overall the largest amount of H2 evolved. This work demonstrates the feasibility of single and multiple gene engineering of microorganisms to redirect their metabolism for improving H2 photoproduction using actual waste-derived substrates.

Maximization of hydrogen production ability in high-density suspension of Rhodovulum sulfidophilum cells using intracellular poly(3-hydroxybutyrate) as sole substrate

Growth of and hydrogen production by wild-type (WT) Rhodovulum sulfidophilum were compared with those by one of its mutants lacking the poly(3-hydroxybutyrate) (PHB) biosynthesis ability (PNM2). During phototrophic growth under aerobic conditions with fixed illumination, changes in the extinction coefficient and PHB content of WT and PNM2 cells revealed interference of light penetration by PHB. WT cells synthesized PHB at an early stage of the cultivation. PHB degradation after exhaustion of acetate during the cultivation of WT resulted in a decrease of the extinction coefficient. The hydrogen production rate under anaerobic conditions with fixed illumination was examined in WT and PNM2 cell suspensions at different densities. The hydrogen production rate was determined not by the light penetration but by the kinds of hydrogen donors and the density of suspension. The highest value of the rate of hydrogen production from PHB, 33.0 ml/l/h, was improved compared with 26.6 ml/l/h, which was the highest value in hydrogen production from succinate. Under the same illumination, conversion to hydrogen from PHB is more efficient than that from succinate, which is one of the best substrates for hydrogen production. These results suggest that the hydrogen production rate can be maximized in the hydrogen production system based on PHB degradation, which is achieved in high-density suspension under external-substrate-depleted conditions after aerobic cultivation in the presence of an excess amount of acetate.

Complex I and its involvement in redox homeostasis and carbon and nitrogen metabolism in Rhodobacter capsulatus

A transposon mutant of Rhodobacter capsulatus, strain Mal7, that was incapable of photoautotrophic and chemoautotrophic growth and could not grow photoheterotrophically in the absence of an exogenous electron acceptor was isolated. The phenotype of strain Mal7 suggested that the mutation was in some gene(s) not previously shown to be involved in CO(2) fixation control. The site of transposition in strain Mal7 was identified and shown to be in the gene nuoF, which encodes one of the 14 subunits for NADH ubiquinone-oxidoreductase, or complex I. To confirm the role of complex I and nuoF for CO(2)-dependent growth, a site-directed nuoF mutant was constructed (strain SBC1) in wild-type strain SB1003. The complex I-deficient strains Mal7 and SBC1 exhibited identical phenotypes, and the pattern of CO(2) fixation control through the Calvin-Benson-Bassham pathway was the same for both strains. It addition, it was shown that electron transport through complex I led to differential control of the two major cbb operons of this organism. Complex I was further shown to be linked to the control of nitrogen metabolism during anaerobic photosynthetic growth of R. capsulatus.

Enhanced hydrogen production by a mutant of Rhodobacter sphaeroides having an altered light-harvesting system

A stable mutant of the photosynthetic bacterium Rhodobacter sphaeroides with an altered light-harvesting (LH) system (P3 mutant) was obtained by UV irradiation and characterized. The mutant exhibited a 2.7-fold decrease in the core antennal (LH1) content and 1.6-fold increase in peripheral antennal (LH2) content compared to the wild-type strain. The H2 evolution rates in the P3 mutant under 800- and 850-nm light, corresponding to the absorption maxima of LH2, were 1.5 times higher than in the wild-type strain. The wild-type absorption spectrum was restored in the P3 mutant when a 1.1-kb PCR-amplified fragment containing the puf promoter and pufQBA genes was ligated into a pRK-415 derivative and introduced into it. The transformant showed lower H2 production rates at 800 and 850 nm than the P3 strain carrying the control plasmid, indicating that the accelerated H2 production in the P3 mutant was a result of alterations in the LH system.

Anaerobic bacterial metabolism in the ancient eukaryote Giardia duodenalis

The protozoan parasite, Giardia duodenalis, shares many metabolic and genetic attributes of the bacteria, including fermentative energy metabolism which relies heavily on pyrophosphate rather than adenosine triphosphate and as a result contains two typically bacterial glycolytic enzymes which are pyrophosphate dependent. Pyruvate decarboxylation and subsequent electron transport to as yet unidentified anaerobic electron acceptors relies on a eubacterial-like pyruvate:ferredoxin oxidoreductase and an archaebacterial/eubacterial-like ferredoxin. The presence of another 2-ketoacid oxidoreductase (with a preference for alpha-ketobutyrate) and multiple ferredoxins in Giardia is also a trait shared with the anaerobic bacteria. Giardia pyruvate:ferredoxin oxidoreductase is distinct from the pyruvate dehydrogenase multienzyme complex invariably found in mitochondria. This is consistent with a lack of mitochondria, citric acid cycle, oxidative phosphorylation and glutathione in Giardia. Giardia duodenalis actively consumes oxygen and yet lacks the conventional mechanisms of oxidative stress management, including superoxide dismutase, catalase, peroxidase, and glutathione cycling, which are present in most eukaryotes. In their place Giardia contains a prokaryotic H2O-producing NADH oxidase, a membrane-associated NADH peroxidase, a broad-range prokaryotic thioredoxin reductase-like disulphide reductase and the low molecular weight thiols, cysteine, thioglycolate, sulphite and coenzyme A. NADH oxidase is a major component of the electron transport pathway of Giardia which, in conjunction with disulphide reductase, protects oxygen-labile proteins such as ferredoxin and pyruvate:ferredoxin oxidoreductase against oxidative stress by maintaining a reduced intracellular environment. As the terminal oxidase, NADH oxidase provides a means of removing excess H+, thereby enabling continued pyruvate decarboxylation and the resultant production of acetate and adenosine triphosphate. A further example of the bacterial-like metabolism of Giardia is the utilisation of the amino acid arginine as an energy source. Giardia contain the arginine dihydrolase pathway, which occurs in a number of anaerobic prokaryotes, but not in other eukaryotes apart from trichomonads and Chlamydomonas reinhardtii. The pathway includes substrate level phosphorylation and is sufficiently active to make a major contribution to adenosine triphosphate production. Two enzymes of the pathway, arginine deiminase and carbamate kinase, are rare in eukaryotes and do not occur in higher animals. Arginine is transported into the trophozoite via a bacterial-like arginine:ornithine antiport. Together these metabolic pathways in Giardia provide a wide range of potential drug targets for future consideration.

A hydrogen-sensing system in transcriptional regulation of hydrogenase gene expression in Alcaligenes species

Heterologous complementation studies using Alcaligenes eutrophus H16 as a recipient identified a hydrogenase-specific regulatory DNA region on megaplasmid pHG21-a of the related species Alcaligenes hydrogenophilus. Nucleotide sequence analysis revealed four open reading frames on the subcloned DNA, designated hoxA, hoxB, hoxC, and hoxJ. The product of hoxA is homologous to a transcriptional activator of the family of two-component regulatory systems present in a number of H2-oxidizing bacteria. hoxB and hoxC predict polypeptides of 34.5 and 52.5 kDa, respectively, which resemble the small and the large subunits of [NiFe] hydrogenases and correlate with putative regulatory proteins of Bradyrhizobium japonicum (HupU and HupV) and Rhodobacter capsulatus (HupU). hoxJ encodes a protein with typical consensus motifs of histidine protein kinases. Introduction of the complete set of genes on a broad-host-range plasmid into A. eutrophus H16 caused severe repression of soluble and membrane-bound hydrogenase (SH and MBH, respectively) synthesis in the absence of H2. This repression was released by truncation of hoxJ. H2-dependent hydrogenase gene transcription is a typical feature of A. hydrogenophilus and differs from the energy and carbon source-responding, H2-independent mode of control characteristic of A. eutrophus H16. Disruption of the A. hydrogenophilus hoxJ gene by an in-frame deletion on megaplasmid pHG21-a led to conversion of the regulatory phenotype: SH and MBH of the mutant were expressed in the absence of H2 in response to the availability of the carbon and energy source. RNA dot blot analysis showed that HoxJ functions on the transcriptional level. These results suggest that the putative histidine protein kinase HoxJ is involved in sensing molecular hydrogen, possibly in conjunction with the hydrogenase-like polypeptides HoxB and HoxC.

HupUV proteins of Rhodobacter capsulatus can bind H2: evidence from the H-D exchange reaction

The H-D exchange reaction has been measured with the D2-H2O system, for Rhodobacter capsulatus JP91, which lacks the hupSL-encoded hydrogenase, and R. capsulatus BSE16, which lacks the HupUV proteins. The hupUV gene products, expressed from plasmid pAC206, are shown to catalyze an H-D exchange reaction distinguishable from the H-D exchange due to the membrane-bound, hupSL-encoded hydrogenase. In the presence of O2, the uptake hydrogenase of BSE16 cells catalyzed a rapid uptake and oxidation of H2, D2, and HD present in the system, and its activity (H-D exchange, H2 evolution in presence of reduced methyl viologen [MV+]) depended on the external pH, while the H-D exchange due to HupUV remained insensitive to external pH and O2. These data suggest that the HupSL dimer is periplasmically oriented, while the HupUV proteins are in the cytoplasmic compartment.

The hupTUV operon is involved in negative control of hydrogenase synthesis in Rhodobacter capsulatus

The hupT, hupU, and hupV genes, which are located upstream from the hupSLC and hypF genes in the chromosome of Rhodobacter capsulatus, form the hupTUV operon expressed from the hupT promoter. The hupU and hupV genes, previously thought to belong to a single open reading frame, encode HupU, of 34.5 kDa (332 amino acids), and HupV, of 50.4 kDa (476 amino acids), which are >/= 50% identical to the homologous Bradyrhizobium japonicum HupU and HupV proteins and Rhodobacter sphaeroides HupU1 and HupU2 proteins, respectively; they also have 20 and 29% similarity with the small subunit (HupS) and the large subunit (HupL), respectively, of R. capsulatus [NiFe]hydrogenase. HupU lacks the signal peptide of HupS and HupV lacks the C-terminal sequence of HupL, which are cleaved during hydrogenase processing. Inactivation of hupV by insertional mutagenesis or of hupUV by in-frame deletion led to HupV- and Hup(UV)- mutants derepressed for hydrogenase synthesis, particularly in the presence of oxygen. These mutants were complemented in trans by plasmid-borne hupTUV but not by hupT or by hupUV, except when expressed from the inducible fru promoter. Complementation of the HupV- and Hup(UV)- mutants brought about a decrease in hydrogenase activity up to 10-fold, to the level of the wild-type strain B10, indicating that HupU and HupV participate in negative regulation of hydrogenase expression in concert with HupT, a sensor histidine kinase involved in the repression process. Plasmid-borne gene fusions used to monitor hupTUV expression indicated that the operon is expressed at a low level (50- to 100-fold lower than hupS).

A new gene expression system based on a fructose-dependent promoter from Rhodobacter capsulatus

Translational lacZ fusions were constructed to analyse transcription of the fructose operon, encoding the fructose-specific phosphotransferase system of Rhodobacter capsulatus. It was demonstrated that transcription from the fru promoter (fruP) was negligible without fructose, and stimulated more than 100-fold by the presence of the inducer. A multiple cloning site, fruP, and a cassette conferring gentamycin resistance were assembled to form a cloning cartridge which is easily transferable to a broad-host-range vector. The sequence initiating the first gene of the fru operon was altered to introduce a NdeI site, allowing insertion of the 5' end of a gene at the correct distance from the ribosome-binding site. The system has been used to express the Escherichia coli lacZ gene in R. capsulatus. beta Gal activity was shown to be specifically and rapidly induced by fructose, at low concentrations. Vectors for fructose-dependent gene expression also proved to be useful in the complementation analysis of mutants. A fdxN mutant of R. capsulatus, markedly impaired in its ability to fix nitrogen due to the lack of a ferredoxin, could be fully complemented using a plasmid carrying a copy of fdxN behind fruP. Complementation, as well as the synthesis of the ferredoxin, were found to be strictly fructose dependent.

Increased Nitrogenase-Dependent H 2 Photoproduction by hup Mutants of Rhodospirillum rubrum

Transposon Tn 5 mutagenesis was used to isolate mutants of Rhodospirillum rubrum which lack uptake hydrogenase (Hup) activity. Three Tn 5 insertions mapped at different positions within the same 13-kb Eco RI fragment (fragment E1). Hybridization experiments revealed homology to the structural hydrogenase genes hupSLM from Rhodobacter capsulatus and hupSL from Bradyrhizobium japonicum in a 3.8-kb Eco RI- Cla I subfragment of fragment E1. It is suggested that this region contains at least some of the structural genes encoding the nickel-dependent uptake hydrogenase of R. rubrum . At a distance of about 4.5 kb from the fragment homologous to hupSLM , a region with homology to a DNA fragment carrying hypDE and hoxXA from B. japonicum was identified. Stable insertion and deletion mutations were generated in vitro and introduced into R. rubrum by homogenotization. In comparison with the wild type, the resulting hup mutants showed increased nitrogenase-dependent H 2 photoproduction. However, a mutation in a structural hup gene did not result in maximum H 2 production rates, indicating that the capacity to recycle H 2 was not completely lost. Highest H 2 production rates were obtained with a mutant carrying an insertion in a nonstructural hup -specific sequence and with a deletion mutant affected in both structural and nonstructural hup genes. Thus, besides the known Hup activity, a second, previously unknown Hup activity seems to be involved in H 2 recycling. A single regulatory or accessory gene might be responsible for both enzymes. In contrast to the nickel-dependent uptake hydrogenase, the second Hup activity seems to be resistant to the metal chelator EDTA.

Recombinant expression of the fdxD gene of Rhodobacter capsulatus and characterization of its product, a [2Fe-2S] ferredoxin

A gene called fdxD that could potentially code for a ferredoxin has recently been identified upstream of the nitrogenase structural genes in Rhodobacter capsulatus [Willison, Pierrard and Hübner (1993) Gene 133, 39-46]. In the present study, the fdxD gene product has been overproduced in Escherichia coli in a soluble form. The recombinant protein, pink in colour, was purified to homogeneity, and biochemically characterized as a new ferredoxin. It represents the fifth ferredoxin so far identified in R. capsulatus and was designated FdV. Its N-terminal sequence is identical with that of the native ferredoxin isolated from R. capsulatus. U.v-visible-absorption spectra as well as results of c.d. and e.p.r. spectroscopy demonstrated that the fdxD product contained a [2Fe-2S] cluster correctly assembled and incorporated into the polypeptide. Although similar to plant-type ferredoxins, FdV appeared poorly competent in the photo-reduction of NADP+. On the basis of in vitro assays, FdV cannot serve as an electron donor for nitrogenase. The lack of reactivity of FdV in either of these assays may primarily be due to its relatively high mid-point redox potential (E'o = -220 mV, pH 7.5).

Photosynthetic electron transport and anaerobic metabolism in purple non-sulfur phototrophic bacteria

Purple non-sulfur phototrophic bacteria, exemplified by Rhodobacter capsulatus and Rhodobacter sphaeroides, exhibit a remarkable versatility in their anaerobic metabolism. In these bacteria the photosynthetic apparatus, enzymes involved in CO2 fixation and pathways of anaerobic respiration are all induced upon a reduction in oxygen tension. Recently, there have been significant advances in the understanding of molecular properties of the photosynthetic apparatus and the control of the expression of genes involved in photosynthesis and CO2 fixation. In addition, anaerobic respiratory pathways have been characterised and their interaction with photosynthetic electron transport has been described. This review will survey these advances and will discuss the ways in which photosynthetic electron transport and oxidation-reduction processes are integrated during photoautotrophic and photoheterotrophic growth.

The IHF proteins of Rhodobacter capsulatus and Pseudomonas aeruginosa

The binding properties of the two IHF consensus sequences present in the promoter region of the hydrogenase structural operon, hupSL, of Rhodobacter capsulatus were studied by gel retardation assays using the heterodimeric IHF-like proteins isolated from R capsulatus, from Pseudomonas aeruginosa and from Escherichia coli. The three IHF proteins bound preferentially to the IHF consensus proximal to hupS. The three-dimensional structure of R capsulatus IHF was modeled using a computer-based amino acid replacement strategy and the known coordinates of crystallized HU protein (HBS) from Bacillus stearothermophilus. Double-stranded DNA and the interaction of IHF and DNA were then modeled using the molecular modeling package Quanta 3.3, and taking into account foot-printing data obtained with IHF-DNA complexes and the fact that the replacement of Arg8 by Cys8 in the alpha subunit, the product of himA, renders R capsulatus IHF ineffective in the activation of hydrogenase synthesis. In this model, IHF is shown to interact with DNA bent by 140 degrees, and Arg8 of HimA capable of interacting with the phosphate-ribose backbone of DNA in the flanking region of the IHF binding site.

Sequence analysis and interposon mutagenesis of the hupT gene, which encodes a sensor protein involved in repression of hydrogenase synthesis in Rhodobacter capsulatus

The hupT gene, which represses hydrogenase gene expression in the purple photosynthetic bacterium Rhodobacter capsulatus, has been identified and sequenced. The nucleotide sequence of hupT and of the contiguous downstream open reading frame, hupU, is reported. The HupT protein of 456 amino acids (48,414 Da) has sequence similarity with the FixL, DctB, NtrB, and ArcB proteins and is predicted to be a soluble sensor kinase. Insertional inactivation of the hupT gene led to deregulation of transcriptional control, so that the hydrogenase structural operon hupSLC became overexpressed in cells grown anaerobically or aerobically. The HupT- mutants were complemented in trans by a plasmid containing an intact copy of the hupT gene. The hupU open reading frame, capable of encoding a protein of 84,879 Da, shared identity with [NiFe]hydrogenase subunits; the strongest similarity was observed with the periplasmic hydrogenase of Desulfovibrio baculatus.

Purification of the integration host factor homolog of Rhodobacter capsulatus: cloning and sequencing of the hip gene, which encodes the beta subunit

We describe a method for rapid purification of the integration host factor (IHF) homolog of Rhodobacter capsulatus that has allowed us to obtain microgram quantities of highly purified protein. R. capsulatus IHF is an alpha beta heterodimer similar to IHF of Escherichia coli. We have cloned and sequenced the hip gene, which encodes the beta subunit. The deduced amino acid sequence (10.7 kDa) has 46% identity with the beta subunit of IHF from E. coli. In gel electrophoretic mobility shift DNA binding assays, R. capsulatus IHF was able to form a stable complex in a site-specific manner with a DNA fragment isolated from the promoter of the structural hupSL operon, which contains the IHF-binding site. The mutated IHF protein isolated from the Hup- mutant IR4, which is mutated in the himA gene (coding for the alpha subunit), gave a shifted band of greater mobility, and DNase I footprinting analysis has shown that the mutated IHF interacts with the DNA fragment from the hupSL promoter region differently from the way that the wild-type IHF does.

Microbial hydrogenases: primary structure, classification, signatures and phylogeny

Thirty sequenced microbial hydrogenases are classified into six classes according to sequence homologies, metal content and physiological function. The first class contains nine H2-uptake membrane-bound NiFe-hydrogenases from eight aerobic, facultative anaerobic and anaerobic bacteria. The second comprises four periplasmic and two membrane-bound H2-uptake NiFe(Se)-hydrogenases from sulphate-reducing bacteria. The third consists of four periplasmic Fe-hydrogenases from strict anaerobic bacteria. The fourth contains eight methyl-viologen- (MV), factor F420- (F420) or NAD-reducing soluble hydrogenases from methanobacteria and Alcaligenes eutrophusH16. The fifth is the H2-producing labile hydrogenase isoenzyme 3 of Escherichia coli. The sixth class contains two soluble tritium-exchange hydrogenases of cyanobacteria. The results of sequence comparison reveal that the 30 hydrogenases have evolved from at least three different ancestors. While those of class I, II, IV and V hydrogenases are homologous, i.e. sharing the same evolutionary origin, both class III and VI hydrogenases are neither related to each other nor to the other classes. Sequence comparison scores, hierarchical cluster structures and phylogenetic trees show that class II falls into two distinct clusters composed of NiFe- and NiFeSe-hydrogenases, respectively. These results also reveal that class IV comprises three distinct clusters: MV-reducing, F420-reducing and NAD-reducing hydrogenases. Specific signatures of the six classes of hydrogenases as well as some subclusters have been detected. Analyses of motif compositions indicate that all hydrogenases, except those of class VI, must contain some common motifs probably participating in the formation of hydrogen activation domains and electron transfer domains. The regions of hydrogen activation domains are highly conserved and can be divided into two categories. One corresponds to the 'nickel active center' of NiFe(Se)-hydrogenases. It consists of two possible specific nickel-binding motifs, RxCGxCxxxH and DPCxxCxxH, located at the N- and C-termini of so-called large subunits in the dimeric hydrogenases, respectively. The other is the H-cluster of the Fe-hydrogenases. It might comprise three motifs on the C-terminal half of the large subunits. However, the motifs corresponding to the putative electron transfer domains, as well as their polypeptides chains, are poorly or even not at all conserved. They are present essentially on the small subunits in NiFe-hydrogenases. Some of these motifs resemble the typical ferredoxin-like Fe-S cluster binding site.(ABSTRACT TRUNCATED AT 400 WORDS)

Biochemical genetics revisited: the use of mutants to study carbon and nitrogen metabolism in the photosynthetic bacteria

The biochemical genetics approach is defined as the use of mutants, in comparative studies with the wild-type, to obtain information about biochemical and physiological processes in complex metabolic systems. This approach has been used extensively, for example in studies on the bioenergetics of the photosynthetic bacteria, but has been applied less frequently to studies of intermediary carbon and nitrogen metabolism in phototrophic organisms. Several important processes in photosynthetic bacteria--the regulation of nitrogenase synthesis and activity, the control of intracellular redox balance during photoheterotrophic growth, and chemotaxis--have been shown to involve metabolism. However, current understanding of carbon and nitrogen metabolism in these organisms is insufficient to allow a complete understanding of these phenomena. The purpose of the present review is to give an overview of carbon and nitrogen metabolism in the photosynthetic bacteria, with particular emphasis on work carried out with mutants, and to indicate areas in which the biochemical genetics approach could be applied successfully. In particular, it will be argued that, in the case of Rhodobacter capsulatus and Rb. sphaeroides, two species which are fast-growing, possess a versatile metabolism, and have been extensively studied genetically, it should be possible to obtain a complete, integrated description of carbon and nitrogen metabolism, and to undertake a qualitative and quantitative analysis of the flow of carbon and reducing equivalents during photoheterotrophic growth. This would require a systematic biochemical genetic study employing techniques such as HPLC, NMR, and mass spectrometry, which are briefly discussed. The review is concerned mainly with Rb. capsulatus and Rb. sphaeroides, since most studies with mutants have been carried out with these organisms. However, where possible, a comparison is made with other species of purple non-sulphur bacteria and with purple and green sulphur bacteria, and recent literature relevant to these organisms has been cited.

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.

Partial purification and characterization of the first hydrogenase isolated from a thermophilic sulfate-reducing bacterium

A soluble [NiFe] hydrogenase has been partially purified from the obligate thermophilic sulfate-reducing bacterium Thermodesulfobacterium mobile. A 17% purification yield was obtained after four chromatographic steps and the hydrogenase presents a purity index (A398 nm/A277 nm) equal to 0.21. This protein appears to be 75% pure on SDS-gel electrophoresis showing two major bands of molecular mass around 55 and 15 kDa. This hydrogenase contains 0.6-0.7 nickel atom and 7-8 iron atoms per mole of enzyme and has a specific activity of 783 in the hydrogen uptake reaction, of 231 in the hydrogen production assay and of 84 in the deuterium-proton exchange reaction. The H2/HD ratio is lower than one in the D2-H+ exchange reaction. The enzyme is very sensitive to NO, relatively little inhibited by CO but unaffected by NO2-. The EPR spectrum of the native hydrogenase shows the presence of a [3Fe-4S] oxidized cluster and of a Ni(III) species.

Expression of regulatory nif genes in Rhodobacter capsulatus

Translational fusions of the Escherichia coli lacZ gene to Rhodobacter capsulatus nif genes were constructed in order to determine the regulatory circuit of nif gene expression in R. capsulatus, a free-living photosynthetic diazotroph. The expression of nifH, nifA (copies I and II), and nifR4 was measured in different regulatory mutant strains under different physiological conditions. The expression of nifH and nifR4 (the analog of ntrA in Klebsiella pneumoniae) depends on the NIFR1/R2 system (the analog of the ntr system in K. pneumoniae), on NIFA, and on NIFR4. The expression of both copies of nifA is regulated by the NIFR1/R2 system and is modulated by the N source of the medium under anaerobic photosynthetic growth conditions. In the presence of ammonia or oxygen, moderate expression of nifA was detectable, whereas nifH and nifR4 were not expressed under these conditions. The implications for the regulatory circuit of nif gene expression in R. capsulatus are discussed and compared with the situation in K. pneumoniae, another free-living diazotroph.