Growth phase-dependant enzyme profile of pyruvate catabolism and end-product formation in Clostridium thermocellum ATCC 27405

End-product synthesis and enzyme activities involved in pyruvate catabolism, H₂ synthesis, and ethanol production in mid-log (OD₆₀₀  0.25), early stationary (OD₆₀₀  0.5), and stationary phase (OD₆₀₀  0.7) cell extracts were determined in Clostridium thermocellum ATCC 27405 grown in batch cultures on cellobiose. Carbon dioxide, hydrogen, ethanol, acetate and formate were major end-products and their production paralleled growth and cellobiose consumption. Lactate dehydrogenase, pyruvate:formate lyase, pyruvate:ferredoxin oxidoreductase, methyl viologen-dependant hydrogenase, ferredoxin-dependant hydrogenase, NADH-dependant hydrogenase, NADPH-dependant hydrogenase, NADH-dependant acetaldehyde dehydrogenase, NADH-dependant alcohol dehydogenase, and NADPH-dependant alcohol dehydrogenase activities were detected in all extracts, while pyruate dehydrogenase and formate dehydrogenase activities were not detected. All hydrogenase activities decreased (2–12-fold) as growth progressed from early exponential to stationary phase. Alcohol dehydrogenase activities fluctuated only marginally (<45%), while lactate dehydrogenase, pyruvate:formate lyase, and pyruvate:ferredoxin oxidoreductase remained constant in all cell extracts. We have proposed a pathway involved in pyruvate catabolism and end-product formation based on enzyme activity profiles in conjunction with bioinformatics analysis.     

End-product induced metabolic shifts in <Emphasis Type="Italic">Clostridium thermocellum</Emphasis> ATCC 27405

When attempting to increase yields of desirable end-products during fermentation, there is the possibility that increased concentrations of one product redirects metabolism towards the synthesis of less desired products. Changes in growth, final end-product concentrations, and activities of enzymes involved in pyruvate catabolism and fermentative end-product formation were studied in Clostridium thermocellum in response to the addition of individual end-products (H₂, acetate, ethanol, formate, and lactate) to the growth medium. These were added to the growth medium at concentrations ten times greater than those found at the end of growth in cultures grown under carbon-limited conditions using cellobiose (1.1 g l⁻¹) as model soluble substrate. Although growth rate and final cell biomass decreased significantly with the addition of all end-products, addition of individual end-products had less pronounced effects on growth. Metabolic shifts, represented by changes in final end-product concentrations, were observed; H₂ and acetate yields increased in the presence of exogenous ethanol and lactate, while ethanol yields increased in the presence of exogenous hydrogen (H₂), acetate, and lactate. Late exponential phase enzyme activity data of enzymes involved in pyruvate catabolism and end-product formation revealed no changes in enzyme levels greater than 2-fold in response to the presence of any given end-product, with the exception of pyruvate:formate lyase (PFL), ferredoxin-dependent hydrogenase (Fd-H₂ase), and pyruvate:ferredoxin oxidoreductase (PFO): PFL and Fd-H₂ase activities increased 2-fold in the presence of ethanol, while PFO activity decreased by 57% in the presence of sodium formate. Changes in enzyme levels did not necessarily correlate with changes in final end-product yields, suggesting that changes in final end-product yields may be governed by thermodynamic considerations rather than levels of enzyme expressed under the conditions tested. We demonstrate that bacterial metabolism may be manipulated in order to selectively improve desired product yields.     

Feminizing Wolbachia: a transcriptomics approach with insights on the immune response genes in Armadillidium vulgare

Background

Clostridium thermocellum produces H₂ and ethanol, as well as CO₂, acetate, formate, and lactate, directly from cellulosic biomass. It is therefore an attractive model for biofuel production via consolidated bioprocessing. Optimization of end-product yields and titres is crucial for making biofuel production economically feasible. Relative protein expression profiles may provide targets for metabolic engineering, while understanding changes in protein expression and metabolism in response to carbon limitation, pH, and growth phase may aid in reactor optimization. We performed shotgun 2D-HPLC-MS/MS on closed-batch cellobiose-grown exponential phase C. thermocellum cell-free extracts to determine relative protein expression profiles of core metabolic proteins involved carbohydrate utilization, energy conservation, and end-product synthesis. iTRAQ (isobaric tag for relative and absolute quantitation) based protein quantitation was used to determine changes in core metabolic proteins in response to growth phase.

Results

Relative abundance profiles revealed differential levels of putative enzymes capable of catalyzing parallel pathways. The majority of proteins involved in pyruvate catabolism and end-product synthesis were detected with high abundance, with the exception of aldehyde dehydrogenase, ferredoxin-dependent Ech-type [NiFe]-hydrogenase, and RNF-type NADH:ferredoxin oxidoreductase. Using 4-plex 2D-HPLC-MS/MS, 24% of the 144 core metabolism proteins detected demonstrated moderate changes in expression during transition from exponential to stationary phase. Notably, proteins involved in pyruvate synthesis decreased in stationary phase, whereas proteins involved in glycogen metabolism, pyruvate catabolism, and end-product synthesis increased in stationary phase. Several proteins that may directly dictate end-product synthesis patterns, including pyruvate:ferredoxin oxidoreductases, alcohol dehydrogenases, and a putative bifurcating hydrogenase, demonstrated differential expression during transition from exponential to stationary phase.

Conclusions

Relative expression profiles demonstrate which proteins are likely utilized in carbohydrate utilization and end-product synthesis and suggest that H₂ synthesis occurs via bifurcating hydrogenases while ethanol synthesis is predominantly catalyzed by a bifunctional aldehyde/alcohol dehydrogenase. Differences in expression profiles of core metabolic proteins in response to growth phase may dictate carbon and electron flux towards energy storage compounds and end-products. Combined knowledge of relative protein expression levels and their changes in response to physiological conditions may aid in targeted metabolic engineering strategies and optimization of fermentation conditions for improvement of biofuels production.     

The Iron-Hydrogenase of Thermotoga maritima Utilizes Ferredoxin and NADH Synergistically: a New Perspective on Anaerobic Hydrogen Production

The hyperthermophilic and anaerobic bacterium Thermotoga maritima ferments a wide variety of carbohydrates, producing acetate, CO₂, and H₂. Glucose is degraded through a classical Embden-Meyerhof pathway, and both NADH and reduced ferredoxin are generated. The oxidation of these electron carriers must be coupled to H₂ production, but the mechanism by which this occurs is unknown. The trimeric [FeFe]-type hydrogenase that was previously purified from T. maritima does not use either reduced ferredoxin or NADH as a sole electron donor. This problem has now been resolved by the demonstration that this hydrogenase requires the presence of both electron carriers for catalysis of H₂ production. The enzyme oxidizes NADH and ferredoxin simultaneously in an approximately 1:1 ratio and in a synergistic fashion to produce H₂. It is proposed that the enzyme represents a new class of bifurcating [FeFe] hydrogenase in which the exergonic oxidation of ferredoxin (midpoint potential, −453 mV) is used to drive the unfavorable oxidation of NADH (E₀′ = −320 mV) to produce H₂ (E₀′ = −420 mV). From genome sequence analysis, it is now clear that there are two major types of [FeFe] hydrogenases: the trimeric bifurcating enzyme and the more well-studied monomeric ferredoxin-dependent [FeFe] hydrogenase. Almost one-third of the known H₂-producing anaerobes appear to contain homologs of the trimeric bifurcating enzyme, although many of them also harbor one or more homologs of the simpler ferredoxin-dependent hydrogenase. The discovery of the bifurcating hydrogenase gives a new perspective on our understanding of the bioenergetics and mechanism of H₂ production and of anaerobic metabolism in general.The order Thermotogales is characterized by the ability of its members to utilize a wide variety of carbohydrates (8). All of these organisms ferment sugars predominantly to acetate, CO₂, and H₂ (23). They thrive mainly at elevated temperatures, although a new subclass of mesophilic “mesotoga” has also been proposed (19). These properties also make the Thermotoga species excellent candidates for biohydrogen production from plant-based biomass. The genome of the type strain, T. maritima, was one of the first to be sequenced, and this revealed a high degree of lateral gene transfer between archaea and bacteria (17, 18). In addition, T. maritima is part of a structural genomics effort, and the structures of over 100 of its proteins have been determined (20, 21). The organism degrades a wide variety of both simple and complex carbohydrates (4, 5), and the glucose that is produced is oxidized by both classical Embden-Meyerhof (85%) and Entner-Douderhoff (15%) pathways (23). The generation of H₂ is accomplished by the enzyme hydrogenase. However, little is known about the bioenergetics of the reaction and the pathways of electron flow from carbohydrate oxidation to H₂ formation.Although hydrogenases catalyze the simplest of chemical reactions, the reversible interconversion of protons, electrons, and H₂, they are surprisingly complex proteins, some more so than others (33). They can be divided into two major groups, the [NiFe]- and [FeFe]-type hydrogenases, based on the presence of nickel and iron or only iron in their active sites. In general, the physiological roles of the [FeFe] hydrogenases are to evolve H₂, while the roles of the [NiFe] enzymes are to oxidize it (33). For example, several Clostridium spp. evolve H₂ via a cytoplasmic, monomeric [FeFe] hydrogenase that uses the low-potential redox protein ferredoxin (Fd) (midpoint potential [E_m], <−400 mV) as the electron donor (15). In contrast, H₂ production using NAD(P)H (E₀′ = −320 mV) as the electron donor is thermodynamically unfavorable under physiological conditions because of the more positive redox potential of the pyridine nucleotides (30). Nevertheless, cytoplasmic NAD(P)H-dependent [FeFe] hydrogenases have been reported, although how the endergonic reaction of NAD(P)H-dependent H₂ production is accomplished under physiological conditions is not clear (13, 28).During the oxidation of glucose by T. maritima, both Fd and NAD function as physiological electron acceptors (1, 26, 34). NADH is generated via the glyceraldehyde-3-phosphate dehydrogenase reaction of glycolysis, while the pyruvate that is generated by this pathway is oxidized by pyruvate Fd oxidoreductase (POR) to acetyl coenzyme A (acetyl-CoA), producing reduced Fd. Acetyl-CoA is converted to acetate by phosphotransacetylase and acetate kinase with the concomitant production of ATP. This pathway leads to the production of four moles of H₂ per mole of glucose, with reductant provided by two moles of NADH and four moles of reduced Fd, together with two moles of acetate and two moles of CO₂ (23). The oxidation of reduced Fd and NADH must be directly or indirectly coupled to the reduction of protons to H₂ by hydrogenase, but the trimeric cytoplasmic [FeFe] hydrogenase characterized from T. maritima more than a decade ago does not use either T. maritima Fd or NADH as the sole electron donor (10, 31). Consequently, the mechanism by which the oxidation of Fd and NADH is coupled in vivo to H₂ production is not known. In this study, we have resolved this long-standing problem by showing that this cytoplasmic enzyme represents a novel type of hydrogenase that requires both physiological electron carriers to be present for the efficient catalysis of H₂ production in which both serve as electron donors.     

The Bidirectional NiFe-hydrogenase in Synechocystis sp. PCC 6803 Is Reduced by Flavodoxin and Ferredoxin and Is Essential under Mixotrophic,Nitrate-limiting Conditions

Cyanobacteria are able to use solar energy for the production of hydrogen. It is generally accepted that cyanobacterial NiFe-hydrogenases are reduced by NAD(P)H. This is in conflict with thermodynamic considerations, as the midpoint potentials of NAD(P)H do not suffice to support the measured hydrogen production under physiological conditions. We show that flavodoxin and ferredoxin directly reduce the bidirectional NiFe-hydrogenase of Synechocystis sp. PCC 6803 in vitro. A merodiploid ferredoxin-NADP reductase mutant produced correspondingly more photohydrogen. We furthermore found that the hydrogenase receives its electrons via pyruvate:flavodoxin/ferredoxin oxidoreductase (PFOR)-flavodoxin/ferredoxin under fermentative conditions, enabling the cells to gain ATP. These results strongly support that the bidirectional NiFe-hydrogenases in cyanobacteria function as electron sinks for low potential electrons from photosystem I and as a redox balancing device under fermentative conditions. However, the selective advantage of this enzyme is not known. No strong phenotype of mutants lacking the hydrogenase has been found. Because bidirectional hydrogenases are widespread in aquatic nutrient-rich environments that are capable of triggering phytoplankton blooms, we mimicked those conditions by growing cells in the presence of increased amounts of dissolved organic carbon and dissolved organic nitrogen. Under these conditions the hydrogenase was found to be essential. As these conditions close the two most important sinks for reduced flavodoxin/ferredoxin (CO₂-fixation and nitrate reduction), this discovery further substantiates the connection between flavodoxin/ferredoxin and the NiFe-hydrogenase.     

Membrane-associated redox activities in Thermotoga neapolitana

Elemental sulfur reduction by the hyperthermophilic bacterium Thermotoga neapolitana provides an alternative to hydrogen evolution during fermentation. Electrons are transferred from reduced cofactors (ferredoxin and NADH) to sulfur by a series of unknown steps. One enzyme that may be involved is an NADH:methyl viologen oxidoreductase (NMOR), an activity that in other fermenting organisms is associated with NADH:ferredoxin oxidoreductase. We found that 83% of NMOR activity was contained in the pellet fraction of cell extracts subjected to ultracentrifugation. This pellet fraction, presumably containing cell membranes, was required for electron transfer to NAD⁺ from ferredoxin-dependent pyruvate oxidation. However, the NMOR activity in this fraction used neither Thermotoga nor clostridial ferredoxins as substrates. NMOR activity was also detected in aerobically prepared vesicles. By comparison with ATPase activities, NMOR was found primarily on the cytoplasmic face of these vesicles. During these studies, an extracytoplasmic hydrogenase activity was discovered. In contrast to the soluble hydrogenase, this hydrogenase activity was completely inhibited when intact cells were treated with cupric chloride and was present on the extracytoplasmic face of vescides. In contrast to a soluble hydrogenase reported in Thermotoga maritima, this activity was air-stable and was inhibited by low concentrations of nitrite. Received: 28 May 1998 / Accepted: 23 June 1998     

Ethanol Production by Thermophilic Bacteria: Relationship Between Fermentation Product Yields of and Catabolic Enzyme Activities in Clostridium thermocellum and Thermoanaerobium brockii

Significant quantitative differences in end-product yields by two strains of Clostridium thermocellum and one strain of Thermoanaerobium brockii were observed during cellobiose fermentation. Most notably, the ethanol/H₂ and lactate/acetate ratios were drastically higher for T. brockii as compared with C. thermocellum strains LQRI and AS39. Exogenous H₂ addition (0.4 to 1.0 atm) during culture growth increased the ethanol/acetate ratio of both T. brockii and AS39 but had no effect on LQRI. All strains had an operative Embden-Meyerhof glycolytic pathway and displayed catabolic activities of fructose-1,6-diphosphate–activated lactate dehydrogenase, coenzyme A acetylating pyruvate and acetaldehyde dehydrogenase, hydrogenase, ethanol dehydrogenase, and acetate kinase. Enzyme kinetic properties (apparent K_m, V_max, and Q₁₀ values) and the specificity of electron donors/acceptors for different oxidoreductases involved in pyruvate conversion to fermentation products were compared in the three strains. Both species contained ferredoxin-linked pyruvate dehydrogenase and pyridine nucleotide oxidoreductases. Ferredoxin-nicotinamide adenine dinucleotide (NAD) reductase activity was significantly higher in T. brockii than in AS39 and was not detectable in LQRI. H₂ production and hydrogenase activity were inversely related to ferredoxin-NAD reductase activity in the three strains. Ferredoxin-NAD phosphate reductase activity was present in cell extracts of both species. Alcohol dehydrogenase activity in C. thermocellum was NAD dependent, unidirectional, and inhibited by low concentrations of NAD and ethanol. Ethanol dehydrogenase activity of T. brockii was both NAD and NADP linked, reversible, and not inhibited by low levels of reaction products. The high lactate yield of T. brockii correlated with increased fructose-1,6-diphosphate. The relation of catabolic enzyme activity and quantitative differences in intracellular electron flow and fermentation product yields of these thermophilic bacteria is discussed.     

Characterization of hydrogenosomes and their role in glucose metabolism of Neocallimastix sp. L2

In the anaerobic fungus Neocallimastix sp. L2 fermentation of glucose proceeds via the Embden-Meyerhof-Parnas pathway. Enzyme activities leading to the formation of succinate, lactate, ethanol, and formate are associated with the cytoplasmic fraction. The enzymes malic enzyme, NAD(P)H: ferredoxin oxidoreductase, pyruvate: ferredoxin oxidoreductase, hydrogenase, acetate: succinate CoA transferase and succinate thiokinase leading to the formation of H₂, CO₂, acetate, and ATP are localized in microbodies. Thus, these organelles are identified as hydrogenosomes. In addition, the microbodies contain the O₂-scavenging enzymes NADH- and NADPH oxidase, while NAD(P)H peroxidase, catalase, or superoxide dismutase could not be detected. In cell-free extracts from zoospores of Neocallimastix sp. L2 the specific activities of hydrogenosomal enzymes as well as the quantities of these proteins are 2- to 6-fold higher than in mycelium extracts. These findings suggest that hydrogenosomes perform an important role-especially in zoospores — as H₂-evolving, ATP-generating and O₂-scavenging organelles.Abbrevations DTT Dithiotreitol - PEP Phosphoenol pyruvate     

Energy transformation coupled to formate oxidation during anaerobic fermentation

A correlation between the rate of ATP synthesis by F₀F₁ ATP synthase and formate oxidation by formate hydrogen lyase (FHL) has been found in inside-out membrane vesicles of the Escherichia coli mutant JW 136 (Δhya/Δhyb) with double deletions of hydrogenases 1 and 2, grown anaerobically on glucose in the absence of external electron acceptors at pH 6.5. ATP synthesis was suppressed by the H⁺-ATPase inhibitors N,N′-dicyclohexylcarbodiimide, sodium azide, and the uncoupler carbonyl cyanide m-chlorophenylhydrazone. Copper ions inhibited formate-dependent hydrogenase and ATP-synthase activities but did not affect the ATPase activity of the vesicles. The maximal rate of ATP synthesis (0.83 μmol/min per mg protein) was determined at simultaneous application of sodium formate, ADP, and inorganic phosphate, and was stimulated by K⁺ ions. The results confirm the assumption of a dual role of hydrogenase 3, the formate hydrogen lyase subunit that can couple the reduction of protons to H₂ and their translocation through membrane with chemiosmotic synthesis of ATP.     

Hydrogen Metabolism in Shewanella oneidensis MR-1

Shewanella oneidensis MR-1 is a facultative sediment microorganism which uses diverse compounds, such as oxygen and fumarate, as well as insoluble Fe(III) and Mn(IV) as electron acceptors. The electron donor spectrum is more limited and includes metabolic end products of primary fermenting bacteria, such as lactate, formate, and hydrogen. While the utilization of hydrogen as an electron donor has been described previously, we report here the formation of hydrogen from pyruvate under anaerobic, stationary-phase conditions in the absence of an external electron acceptor. Genes for the two S. oneidensis MR-1 hydrogenases, hydA, encoding a periplasmic [Fe-Fe] hydrogenase, and hyaB, encoding a periplasmic [Ni-Fe] hydrogenase, were found to be expressed only under anaerobic conditions during early exponential growth and into stationary-phase growth. Analyses of ΔhydA, ΔhyaB, and ΔhydA ΔhyaB in-frame-deletion mutants indicated that HydA functions primarily as a hydrogen-forming hydrogenase while HyaB has a bifunctional role and represents the dominant hydrogenase activity under the experimental conditions tested. Based on results from physiological and genetic experiments, we propose that hydrogen is formed from pyruvate by multiple parallel pathways, one pathway involving formate as an intermediate, pyruvate-formate lyase, and formate-hydrogen lyase, comprised of HydA hydrogenase and formate dehydrogenase, and a formate-independent pathway involving pyruvate dehydrogenase. A reverse electron transport chain is potentially involved in a formate-hydrogen lyase-independent pathway. While pyruvate does not support a fermentative mode of growth in this microorganism, pyruvate, in the absence of an electron acceptor, increased cell viability in anaerobic, stationary-phase cultures, suggesting a role in the survival of S. oneidensis MR-1 under stationary-phase conditions.     

Dissection of the caffeate respiratory chain in the acetogen Acetobacterium woodii: identification of an Rnf-type NADH dehydrogenase as a potential coupling site

The anaerobic acetogenic bacterium Acetobacterium woodii couples caffeate reduction with electrons derived from hydrogen to the synthesis of ATP by a chemiosmotic mechanism with sodium ions as coupling ions, a process referred to as caffeate respiration. We addressed the nature of the hitherto unknown enzymatic activities involved in this process and their cellular localization. Cell extract of A. woodii catalyzes H₂-dependent caffeate reduction. This reaction is strictly ATP dependent but can be activated also by acetyl coenzyme A (CoA), indicating that there is formation of caffeyl-CoA prior to reduction. Two-dimensional gel electrophoresis revealed proteins present only in caffeate-grown cells. Two proteins were identified by electrospray ionization-mass spectrometry/mass spectrometry, and the encoding genes were cloned. These proteins are very similar to subunits α (EtfA) and β (EtfB) of electron transfer flavoproteins present in various anaerobic bacteria. Western blot analysis demonstrated that they are induced by caffeate and localized in the cytoplasm. Etf proteins are known electron carriers that shuttle electrons from NADH to different acceptors. Indeed, NADH was used as an electron donor for cytosolic caffeate reduction. Since the hydrogenase was soluble and used ferredoxin as an electron acceptor, the missing link was a ferredoxin:NAD⁺ oxidoreductase. This activity could be determined and, interestingly, was membrane bound. A search for genes that could encode this activity revealed DNA fragments encoding subunits C and D of a membrane-bound Rnf-type NADH dehydrogenase that is a potential Na⁺ pump. These data suggest the following electron transport chain: H₂ → ferredoxin → NAD⁺ → Etf → caffeyl-CoA reductase. They also imply that the sodium motive step in the chain is the ferredoxin-dependent NAD⁺ reduction catalyzed by Rnf.     

Genetic Examination and Mass Balance Analysis of Pyruvate/Amino Acid Oxidation Pathways in the Hyperthermophilic Archaeon Thermococcus kodakarensis

The present study investigated the simultaneous oxidation of pyruvate and amino acids during H₂-evolving growth of the hyperthermophilic archaeon Thermococcus kodakarensis. The comparison of mass balance between a cytosolic hydrogenase (HYH)-deficient strain (the ΔhyhBGSL strain) and the parent strain indicated that NADPH generated via H₂ uptake by HYH was consumed by reductive amination of 2-oxoglutarate catalyzed by glutamate dehydrogenase. Further examinations were done to elucidate functions of three enzymes potentially involved in pyruvate oxidation: pyruvate formate-lyase (PFL), pyruvate:ferredoxin oxidoreductase (POR), and 2-oxoisovalerate:ferredoxin oxidoreductase (VOR) under the HYH-deficient background in T. kodakarensis. No significant change was observed by deletion of pflDA, suggesting that PFL had no critical role in pyruvate oxidation. The growth properties and mass balances of ΔporDAB and ΔvorDAB strains indicated that POR and VOR specifically functioned in oxidation of pyruvate and branched-chain amino acids, respectively, and the lack of POR or VOR was compensated for by promoting the oxidation of another substrate driven by the remaining oxidoreductase. The H₂ yields from the consumed pyruvate and amino acids were increased from 31% by the parent strain to 67% and 82% by the deletion of hyhBGSL and double deletion of hyhBGSL and vorDAB, respectively. Significant discrepancies in the mass balances were observed in excess formation of acetate and NH₃, suggesting the presence of unknown metabolisms in T. kodakarensis grown in the rich medium containing pyruvate.     

The genome of Syntrophorhabdus aromaticivorans strain UI provides new insights for syntrophic aromatic compound metabolism and electron flow

How aromatic compounds are degraded in various anaerobic ecosystems (e.g. groundwater, sediments, soils and wastewater) is currently poorly understood. Under methanogenic conditions (i.e. groundwater and wastewater treatment), syntrophic metabolizers are known to play an important role. This study explored the draft genome of Syntrophorhabdus aromaticivorans strain UI and identified the first syntrophic phenol‐degrading phenylphosphate synthase (PpsAB) and phenylphosphate carboxylase (PpcABCD) and syntrophic terephthalate‐degrading decarboxylase complexes. The strain UI genome also encodes benzoate degradation through hydration of the dienoyl‐coenzyme A intermediate as observed in Geobacter metallireducens and Syntrophus aciditrophicus. Strain UI possesses electron transfer flavoproteins, hydrogenases and formate dehydrogenases essential for syntrophic metabolism. However, the biochemical mechanisms for electron transport between these H₂/formate‐generating proteins and syntrophic substrate degradation remain unknown for many syntrophic metabolizers, including strain UI. Analysis of the strain UI genome revealed that heterodisulfide reductases (HdrABC), which are poorly understood electron transfer genes, may contribute to syntrophic H₂ and formate generation. The genome analysis further identified a putative ion‐translocating ferredoxin : NADH oxidoreductase (IfoAB) that may interact with HdrABC and dissimilatory sulfite reductase gamma subunit (DsrC) to perform novel electron transfer mechanisms associated with syntrophic metabolism.     

Function of reduced pyridine nucleotide-ferredoxin oxidoreductases in saccharolytic Clostridia

The physiological function of the clostridial NADH- and NADPH-ferredoxin oxidoreductases was investigated with Clostridium pasteurianum and Clostridium butyricum.The NADH-ferredoxin oxidoreductases are concluded to be catabolic enzymes required for the reduction of ferredoxin by NADH. The conclusion is based on the finding that during the entire growth phase the fermentation of glucose can be formally represented by the weighted sum of Eqns 1 and 2, Glucose + 2 H₂O → 1 butyrate^? + 2 HCO₃^? + 3 H⁺ + 2 H₂ (1) Glucose + 4 H₂O → 2 acetate^? + 2 HCO₃^? + 4 H⁺ + 4 H₂ (2) and that in these redox processes NADH rather than NADPH is specifically formed during glyceraldehyde phosphate dehydrogenation. This NADH can be consumed by substrate reduction in Process 1 only, while it must be reoxidized in Process 2 by the ferredoxin-dependent proton reduction to hydrogen which involves the NADH-ferredoxin oxidoreductases.The kinetic and regulatory properties of these enzymes are in line with their catabolic role: they are found with high specific activities typical for other catabolic enzymes; essentially they catalyze electron flow from NADH to ferredoxin only because the back reaction is very effectively inhibited by low concentrations of NADH. These enzymes have a key role in the coupling of the two partial processes and in regulating the overall thermodynamic efficiency of the fermentations.The NADPH-ferredoxin oxidoreductases are concluded to participate in anabolism; they are required for the regeneration of NADPH. The conclusion is based on the finding that in the two clostridia all catabolic oxidations-reductions are specific for NAD(H) and that the usual NADPH-producing processes such as the glucose 6-phosphate dehydrogenase or malate enzyme reactions are absent. The kinetic properties of the enzymes are in agreement with their anabolic function: the NADPH-ferredoxin oxidoreductases are found with sufficient specific activities; they preferentially catalyze electron transfer from reduced ferredoxin to NADP⁺.     

Purification of Hydrogenase from Chlamydomonas reinhardtii

A method is described which results in a 2750-fold purification of hydrogenase from Chlamydomonas reinhardtii, yielding a preparation which is approximately 40% pure. With a saturating amount of ferredoxin as the electron mediator, the specific activity of pure enzyme was calculated to be 1800 micromoles H₂ produced per milligram protein per minute. The molecular weight was determined to be 4.5 × 10⁴ by gel filtration and 4.75 × 10⁴ by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme has an abundance of acidic side groups, contains iron, and has an activation energy of 55.1 kilojoules per mole for H₂ production; these properties are similar to those of bacterial hydrogenases. The enzyme is less thermally stable than most bacterial hydrogenases, however, losing 50% of its activity in 1 hour at 55°C. The K_m of purified hydrogenase for ferredoxin is 10 micromolar, and the binding of these proteins to each other is enhanced under slightly acidic conditions. Purified hydrogenase also accepts electrons from a variety of artificial electron mediators, including sodium metatungstate, sodium silicotungstate, and several viologen dyes. A lag period is frequently observed before maximal activity is expressed with these artificial electron mediators, although the addition of sodium thiosulfate at least partially overcomes this lag.     

Coupled ferredoxin and crotonyl coenzyme A (CoA) reduction with NADH catalyzed by the butyryl-CoA dehydrogenase/Etf complex from Clostridium kluyveri

Cell extracts of butyrate-forming clostridia have been shown to catalyze acetyl-coenzyme A (acetyl-CoA)- and ferredoxin-dependent formation of H₂ from NADH. It has been proposed that these bacteria contain an NADH:ferredoxin oxidoreductase which is allosterically regulated by acetyl-CoA. We report here that ferredoxin reduction with NADH in cell extracts from Clostridium kluyveri is catalyzed by the butyryl-CoA dehydrogenase/Etf complex and that the acetyl-CoA dependence previously observed is due to the fact that the cell extracts catalyze the reduction of acetyl-CoA with NADH via crotonyl-CoA to butyryl-CoA. The cytoplasmic butyryl-CoA dehydrogenase complex was purified and is shown to couple the endergonic reduction of ferredoxin (E₀′ = −410 mV) with NADH (E₀′ = −320 mV) to the exergonic reduction of crotonyl-CoA to butyryl-CoA (E₀′ = −10 mV) with NADH. The stoichiometry of the fully coupled reaction is extrapolated to be as follows: 2 NADH + 1 oxidized ferredoxin + 1 crotonyl-CoA = 2 NAD⁺ + 1 ferredoxin reduced by two electrons + 1 butyryl-CoA. The implications of this finding for the energy metabolism of butyrate-forming anaerobes are discussed in the accompanying paper.     

Utilization of free and immobilized Desulfovibrio hydrogenase in hydrogen photoproduction : Coupling efficiency of cytochrome C3, ferredoxin and flavodoxin

Summary Hydrogen photoproduction has been achieved by coupling free or immobilized hydrogenases from Desulfovibrio species to illuminated chloroplasts through different electron mediators. Whereas D. gigas flavodoxin or ferredoxin I cannot directly mediate the electron flux from chloroplasts to hydrogenase, the addition of these mediators considerably enhances the H₂ photoproduction of a system including cytochrome C₃. These immobilized hydrogenases exhibit good stability under working conditions and can be re-used.     

Combinatorial assembly of ferredoxin-linked modules in Escherichia coli yields a testing platform for Rnf-complexes

The Rnf complex is a membrane-bound ferredoxin(Fd):NAD(P)⁺ oxidoreductase (Fno) that couples Fd oxidation to vectorial H⁺/Na⁺ transport across the cytoplasmic membrane. Here, we produced two putative Rnf-complexes from Clostridioides difficile (Cd-Rnf) and Clostridium ljungdahlii (Cl-Rnf) for the first time in Escherichia coli. A redox-responsive low-expression system enabled Rnf assembly in the membranes of E. coli as confirmed by in vitro activity measurements. To study the physiological effects of Rnf on the metabolism of E. coli, we assembled additional Fd-dependent enzymes by plasmid-based multigene expression: (a) an Fd-linked butyrate pathway (But) from C. difficile, (b) an [FeFe]-hydrogenase (Hyd) to modulate the redox state of Fd, and (c) heterologous ferredoxins as electron carriers. The hydrogenase efficiently modulated butyrate formation by H₂-mediated Fd reoxidation under nitrogen. In its functionally assembled state, Rnf severely impaired cell growth. Including Hyd in the But/Rnf background, in turn, restored normal growth. Our findings suggest that Rnf mediates reverse electron flow from NADH to Fd, which requires E. coli’s F-type ATPase to function in its reverse, ATP hydrolyzing direction. The reduced Fd is then reoxidized by endogenous Fd:NAD(P)H oxidoreductase (Fpr), which regenerates NADH and, thereby, initiates a futile cycle fueled by ATP hydrolysis. The introduction of hydrogenase interrupts this futile cycle under N₂ by providing an efficient NAD(P)⁺-independent Fd reoxidation route, whereas under H₂, Hyd outcompetes Rnf for Fd reduction. This is the first report of an Rnf complex being functionally produced and physiologically investigated in E. coli.