Sodium dependence of acetate formation by the acetogenic bacterium Acetobacterium woodii.

Growth of Acetobacterium woodii on fructose was stimulated by Na+; this stimulation was paralleled by a shift of the acetate-fructose ratio from 2.1 to 2.7. Growth on H2-CO2 or on methanol plus CO2 was strictly dependent on the presence of sodium ions in the medium. Acetate formation from formaldehyde plus H2-CO by resting cells required Na+, but from methanol plus H2-CO did not. This is analogous to H2-CO2 reduction to methane by Methanosarcina barkeri, which involves a sodium pump (V. Müller, C. Winner, and G. Gottschalk, Eur. J. Biochem. 178:519-525, 1988). This suggests that the reduction of methylenetetrahydrofolate to methyltetrahydrofolate is the Na+-requiring reaction. A sodium gradient (Na+ out/Na+ in = 32, delta pNa = -91 mV) was built up when resting cells of A. woodii were incubated under H2-CO2. Acetogenesis was inhibited when the delta pNa was dissipated by monensin.     

Regulation of caffeate respiration in the acetogenic bacterium Acetobacterium woodii

The anaerobic acetogenic bacterium Acetobacterium woodii can conserve energy by oxidation of various substrates coupled to either carbonate or caffeate respiration. We used a cell suspension system to study the regulation and kinetics of induction of caffeate respiration. After addition of caffeate to suspensions of fructose-grown cells, there was a lag phase of about 90 min before caffeate reduction commenced. However, in the presence of tetracycline caffeate was not reduced, indicating that de novo protein synthesis is required for the ability to respire caffeate. Induction also took place in the presence of CO(2), and once a culture was induced, caffeate and CO(2) were used simultaneously as electron acceptors. Induction of caffeate reduction was also observed with H(2) plus CO(2) as the substrate, but the lag phase was much longer. Again, caffeate and CO(2) were used simultaneously as electron acceptors. In contrast, during oxidation of methyl groups derived from methanol or betaine, acetogenesis was the preferred energy-conserving pathway, and caffeate reduction started only after acetogenesis was completed. The differential flow of reductants was also observed with suspensions of resting cells in which caffeate reduction was induced prior to harvest of the cells. These cell suspensions utilized caffeate and CO(2) simultaneously with fructose or hydrogen as electron donors, but CO(2) was preferred over caffeate during methyl group oxidation. Caffeate-induced resting cells could reduce caffeate and also p-coumarate or ferulate with hydrogen as the electron donor. p-Coumarate or ferulate also served as an inducer for caffeate reduction. Interestingly, caffeate-induced cells reduced ferulate in the absence of an external reductant, indicating that caffeate also induces the enzymes required for oxidation of the methyl group of ferulate.     

A sodium-stimulated ATP synthase in the acetogenic bacterium Acetobacterium woodii.

Experiments with resting cells of Acetobacterium woodii were performed to elucidate the coupling ion used by the ATP synthase. A. woodii synthesized ATP in response to an artificial delta pH, indicating the presence of a proton-translocating ATPase. On the other hand, a delta pNa, as well as a proton diffusion potential, could serve as a driving force for ATP synthesis with the latter strictly dependent on Na+. These results are indicative for the presence of a Na(+)-translocating ATP synthase in A. woodii.     

A Na+-translocating pyrophosphatase in the acetogenic bacterium Acetobacterium woodii

The anaerobic acetogenic bacterium Acetobacterium woodii employs a novel type of Na(+)-motive anaerobic respiration, caffeate respiration. However, this respiration is at the thermodynamic limit of energy conservation, and even worse, in the first step, caffeate is activated by caffeyl-CoA synthetase, which hydrolyzes ATP to AMP and pyrophosphate. Here, we have addressed whether or not the energy stored in the anhydride bond of pyrophosphate is conserved by A. woodii. Inverted membrane vesicles of A. woodii have a membrane-bound pyrophosphatase that catalyzes pyrophosphate hydrolysis at a rate of 70-120 milliunits/mg of protein. Pyrophosphatase activity was dependent on the divalent cation Mg(2+). In addition, activity was strictly dependent on Na(+) with a K(m) of 1.1 mM. Hydrolysis of pyrophosphate was accompanied by (22)Na(+) transport into the lumen of the inverted membrane vesicles. Inhibitor studies revealed that (22)Na(+) transport was primary and electrogenic. Next to the Na(+)-motive ferredoxin:NAD(+) oxidoreductase (Fno or Rnf), the Na(+)-pyrophosphatase is the second primary Na(+)-translocating enzyme in A. woodii.     

Adh4, an alcohol dehydrogenase controls alcohol formation within bacterial microcompartments in the acetogenic bacterium Acetobacterium woodii

Acetobacterium woodii utilizes the Wood-Ljungdahl pathway for reductive synthesis of acetate from carbon dioxide. However, A. woodii can also perform non-acetogenic growth on 1,2-propanediol (1,2-PD) where instead of acetate, equal amounts of propionate and propanol are produced as metabolic end products. Metabolism of 1,2-PD occurs via encapsulated metabolic enzymes within large proteinaceous bodies called bacterial microcompartments. While the genome of A. woodii harbours 11 genes encoding putative alcohol dehydrogenases, the BMC-encapsulated propanol-generating alcohol dehydrogenase remains unidentified. Here, we show that Adh4 of A. woodii is the alcohol dehydrogenase required for propanol/ethanol formation within these microcompartments. It catalyses the NADH-dependent reduction of propionaldehyde or acetaldehyde to propanol or ethanol and primarily functions to recycle NADH within the BMC. Removal of adh4 gene from the A. woodii genome resulted in slow growth on 1,2-PD and the mutant displayed reduced propanol and enhanced propionate formation as a metabolic end product. In sum, the data suggest that Adh4 is responsible for propanol formation within the BMC and is involved in redox balancing in the acetogen, A. woodii.     

Biosynthesis of butyrate from methanol and carbon monoxide by recombinant Acetobacterium woodii

International Microbiology - Methanol is one of the most widely produced organic substrates from syngas and can serve as a bio-feedstock to cultivate acetogenic bacteria which allows a major...     

A caffeyl-coenzyme A synthetase initiates caffeate activation prior to caffeate reduction in the acetogenic bacterium Acetobacterium woodii

The anaerobic acetogenic bacterium Acetobacterium woodii couples the reduction of caffeate with electrons derived from hydrogen to the synthesis of ATP by a chemiosmotic mechanism using sodium ions as coupling ions, but the enzymes involved remain to be established. Previously, the electron transfer flavoproteins EtfA and EtfB were found to be involved in caffeate respiration. By inverse PCR, we identified three genes upstream of etfA and etfB: carA, carB, and carC. carA encodes a potential coenzyme A (CoA) transferase, carB an acyl-CoA synthetase, and carC an acyl-CoA dehydrogenase. carA, -B, and -C are located together with etfA/carE and etfB/carD on one polycistronic message, indicating that CarA, CarB, and CarC are also part of the caffeate respiration pathway. The genetic data suggest an initial ATP-dependent activation of caffeate by CarB. To prove the proposed function of CarB, the protein was overproduced in Escherichia coli, and the recombinant protein was purified. Purified CarB activates caffeate to caffeyl-CoA in an ATP- and CoA-dependent reaction. The enzyme has broad pH and temperature optima and requires K(+) for activity. In addition to caffeate, it can use ρ-coumarate, ferulate, and cinnamate as substrates, with 50, 15, and 9%, respectively, of the activity obtained with caffeate. Expression of the car operon is induced not only by caffeate, ρ-coumarate, ferulate, and cinnamate but also by sinapate. There is no induction by ρ-hydroxybenzoate or syringate.     

Carrier-mediated acetate transport in Acetobacterium woodii

Intracellular and extracellular acetate concentrations of Acetobacterium woodii DSM 1030 were determined during growth or incubation of resting cell suspensions. The internal concentrations during growth decreased from initially 350 mM to 145 mM at the end of the experiment. The intracellular pH was lowered from 7.5 to 6.6 and the pH was enlarged from 0.2 to 0.6 units. Both, growing and resting cells of A. woodii showed no equilibrium between internal and external acetate concentrations during glucose consumption; the internal concentrations were always higher than expected assuming equal concentrations of the free acid inside and outside the cells. From counterflow experiments it is suggested that acetate does not only leave A. woodii cells by passive diffusion but also by carrier-mediated transport.     

Carbonic anhydrase in Acetobacterium woodii and other acetogenic bacteria.

Acetobacterium woodii, Acetohalobium arabaticum, Clostridium formicoaceticum, and Sporomusa silvacetica were found to contain carbonic anhydrase (CA). Minimal to no CA activity was detected in Moorella thermoautotrophica, Moorella thermoacetica subsp. "pratumsolum," Sporomusa termitida, and Thermoanaerobacter kivui. Of the acetogens tested, A. woodii had the highest CA specific activity, approximately 14 U mg of protein(-1), in extracts of either glucose- or H2-CO2-cultivated cells. CA of A. woodii was cytoplasmic and was purified approximately 300-fold to a specific activity of 5,236 U mg of protein(-1). Intracellular acetate concentrations inhibited CA activity of A. woodii by 50 to 85%, indicating that intracellular acetate may affect in situ CA activity.     

The Rnf complex from the acetogenic bacterium Acetobacterium woodii: Purification and characterization of RnfC and RnfB

rnf genes are widespread in anaerobic bacteria and hypothesized to encode a respiratory enzyme that couples exergonic reduction of NAD with reduced ferredoxin as a reductant to vectorial ion (Na⁺, H⁺) translocation across the cytoplasmic membrane. However, despite its importance for the physiology of these bacteria, little is known about the subunit composition and the function of subunits. Here, we have purified the entire Rnf complex from the acetogen Acetobacterium woodii or after its production in Escherichia coli. These studies revealed covalently bound flavin in RnfB and RnfD. Unfortunately, the complex did not catalyze electron transfer from reduced ferredoxin to NAD. We, therefore, concentrated on the two cytosolic subunits RnfC and RnfB. RnfC was produced in E. coli, purified and shown to have 8.3 mol iron and 8.6 mol sulfur per mol of the subunit, consistent with the presence of two [4Fe-4S] centers, which were verified by EPR analysis. Flavins could not be detected, but RnfC catalyzed NADH-dependent FMN reduction. These data confirm RnfC as NADH-binding subunit and FMN as an intermediate in the electron transport chain. RnfB could only be produced as a fusion to the maltose-binding protein. It contained 25 mol iron and 26 mol sulfur, consistent with the predicted six [4Fe4S] centers. The FeS centers in RnfB were reduced with reduced ferredoxin as reductant. These data are consistent with RnfB as the ferredoxin-binding subunit of the complex.     

Improvement of the long-term survival of Acetobacterium woodii by limiting acetate production

Summary The viable count in fructose-grown cultures of Acetobacterium woodii fell to undetectable levels 186 h after the stationary phase was reached. The loss of viability was due to accumulation of undissociated acetic acid, since loss of viability could be induced artificially in cultures grown at pH 6.8 by adjusting the pH to 5.0 or by adding high concentrations of acetate. Survival was greatly improved when cultures were grown at low initial fructose concentrations ( 2 g/l) to limit acetate production, since viable cells could still be detected after 73d.     

Isolation of carbon monoxide dehydrogenase from Acetobacterium woodii and comparison of its properties with those of the Clostridium thermoaceticum enzyme.

An oxygen-labile carbon monoxide dehydrogenase was purified to at least 98% homogeneity from fructose-grown cells of Acetobacterium woodii. Gel filtration and electrophoresis experiments gave molecular weights of 480,000 and 153,000, respectively, of the active enzyme. The molecular weights for the subunits are 80,000 and 68,000; the subunits occur in equal proportion. The small subunit of the A. woodii enzyme differs in size from that of the Clostridium thermoaceticum enzyme; however, the large subunits are similar. The specific activity of the A. woodii enzyme, measured at 30 degrees C and pH 7.6, is 500 mumol of CO oxidized min-1 mg-1 with 20 mM methyl viologen as the electron acceptor. Analysis revealed (number per dimer) iron (9), acid-labile sulfide (12), nickel (1.4), and magnesium or zinc (1). This metal content is quite similar to that of the C. thermoaceticum enzyme (Ragsdale et al., J. Biol. Chem. 258:2364-2369, 1983). The nickel as well as the iron-sulfur clusters are redox-active, as was found for the C. thermoaceticum enzyme (Ragsdale et al., Biochem. Biophys. Res. Commun. 108:658-663, 1982). CO can reduce and CO2 can oxidize the iron-sulfur clusters. The enzyme is inhibited by cyanide, but CO2 in the presence of reduced methyl viologen or CO alone can reverse or prevent this inhibition. Several ferredoxins, flavodoxin, and rubredoxin and some artificial electron carriers were tested for their relative rates of reaction with the CO dehydrogenases from A. woodii, C. thermoaceticum, and Clostridium formicoaceticum. Rubredoxin was by far the most reactive acceptor and is proposed to be the primary natural electron carrier for the acetogenic CO dehydrogenases.     

Electron microscopic investigation of the hydrogen-oxidizing acetate-forming anaerobic bacterium Acetobacterium woodii

Acetobacterium woodii is a Gram-positive anaerobic nonsporeforming bacterium able to grow on H₂ and CO₂ as sole sources of energy. The product of fermentation is acetic acid. Fine structural analysis showed rod-shaped flagellated cells, and coccoid cells without flagella arranged predominantly in pairs and chains. The cell wall was found to be composed of three layers. The cell surface exhibited a periodic array of particles consisting of subunits. The cytoplasmic membrane showed particles either either in random distribution or in a hexagonal pattern. Intracytoplasmic membranes were rarely observed, whereas inclusion bodies of varying shapes, predominantly in an uncommon disc-shape, could frequently be observed. Their content was dissolved in ultrathin sections indicating hydrophobic nature.     

Tetrahydrofolate enzyme levels in Acetobacterium woodii and their implication in the synthesis of acetate from CO2

Acetate synthesis from CO2 by Acetobacterium woodii may occur as in homoacetate-fermenting clostridia, as indicated by high levels of enzymes of the tetrahydrofolate pathway and by pyruvate-dependent formation of acetate from methyl-B12 and methyltetrahydrofolate.     

Transformation of tetrachloromethane to dichloromethane and carbon dioxide by Acetobacterium woodii

Five anaerobic bacteria were tested for their abilities to transform tetrachloromethane so that information about enzymes involved in reductive dehalogenations of polychloromethanes could be obtained. Cultures of the sulfate reducer Desulfobacterium autotrophicum transformed some 80 microM tetrachloromethane to trichloromethane and a small amount of dichloromethane in 18 days under conditions of heterotrophic growth. The acetogens Acetobacterium woodii and Clostridium thermoaceticum in fructose-salts and glucose-salts media, respectively, degraded some 80 microM tetrachloromethane completely within 3 days. Trichloromethane accumulated as a transient intermediate, but the only chlorinated methanes recovered at the end of the incubation were 8 microM dichloromethane and traces of chloromethane. Desulfobacter hydrogenophilus and an autotrophic, nitrate-reducing bacterium were unable to transform tetrachloromethane. Reduction of chlorinated methanes was thus observed only in the organisms with the acetyl-coenzyme A pathway. Experiments with [14C]tetrachloromethane were done to determine the fate of this compound in the acetogen A. woodii. Radioactivity in an 11-day heterotrophic culture was largely (67%) recovered in CO2, acetate, pyruvate, and cell material. In experiments with cell suspensions to which [14C]tetrachloromethane was added, 14CO2 appeared within 20 s as the major transformation product. A. woodii thus catalyzes reductive dechlorinations and transforms tetrachloromethane to CO2 by a series of unknown reactions.     

Purification and properties of the coenzyme A-linked acetaldehyde dehydrogenase of Acetobacterium woodii

Coenzyme A-linked acetaldehyde dehydrogenase (ACDH) of ethanol-grown cells of Acetobacterium woodii was purified to apparent homogeneity; a 28-fold purification was achieved with 13% yield. The enzyme proved to be oxygen-sensitive and was inactive in the absence of dithioerythritol. During the purification procedure addition of 1 mM MgCl₂ was necessary to maintain enzyme activity. Alcohol dehydrogenase (ADH) activity was separated from ACDH during anion exchange chromatography using DEAE Sephacel. A part of the ACDH activity coeluted with ADH, but both could be separately eluted from a Cibacron Blue 3GA-Agarose column, revealing the same subunit structure and activity band for ACDH as found before and, thus, indicating an aggregation of the enzyme. The remaining ADH activity could be separated by gel filtration. For the native ACDH a molecular mass of 255 kDa was determined by polyacrylamide gel electrophoresis and of 272 kDa by gel filtration using Superose 12. The enzyme subunit sizes were 28 kDa and 40 kDa, respectively, indicating a ₄₄ structure for the active form. The enzyme catalyzed the oxidation of several straight chain aldehydes although it was most active with acetaldehyde. NADH strongly inhibited oxidation of acetaldehyde whereas NADPH had no effect. The inhibition was noncompetitive.Non-standard abbrevations ACDH acetaldehyde dehydrogenase - ADH alcohol dehydrogenase - CHES 2-(N-cyclohexylamino)-ethanesulfonate - DTE dithioerythritol - KP-buffer 25 mM K-PO₄, pH 7.5, containing, 4 mM DTE - MES 2-(N-morpholino)-ethanesulfonate - TAPS N-Tris-(hydroxymethyl)-methyl-3-aminopropa-nesulfonate