The adaptive genome of Desulfovibrio vulgaris Hildenborough

Peculiar attributes revealed by sequencing the genome of Desulfovibrio vulgaris Hildenborough are analyzed, particularly in relation to the presence of a phosphotransferase system (PTS). The PTS is a typical bacterial carbohydrate transport system functioning via group translocation. Novel avenues for investigations are proposed emphasizing the metabolic diversity of D. vulgaris Hildenborough, especially the likely utilization of mannose-type sugars. Comparative analysis with PTS from other Gram-negative and Gram-positive bacteria indicates regulatory functions for the PTS of D. vulgaris Hildenborough, including catabolite repression and inducer exclusion. Chemotaxis towards PTS substrates is considered. Evidence suggests that this organism may not be a strict anaerobic sulfate reducer typical of the ocean, but a versatile organism capable of bidirectional transmigration and adaptation to both water and terrestrial environments.     

NMR redox studies of Desulfovibrio vulgaris Cytochrome c3. Electron transfer mechanisms

The 300-MHz proton NMR spectra of the tetrahaem cytochrome c3 from Desulfovibrio vulgaris were examined while varying the pH and the redox potential. The analysis of the complete NMR reoxidation pattern was done taking into account all the 16 redox states that can be present in the redox titration of a tetra-redox-center molecule. A network of saturation transfer experiments performed at different oxidation stages, between the fully reduced and the fully oxidized states, allowed the observation of different resonances for some of the haem methyl groups. In the present experimental conditions, some of the haems show a fast intramolecular electron exchange rate, but the intermolecular electron exchange is always slow. In intermediate reoxidation stages, large shifts of the resonances of some haem methyl groups were observed upon changing the pH. These shifts are discussed in terms of a pH dependence of the haem midpoint redox potentials. The physiological relevance of this pH dependence is discussed.     

Thiosulfate Reductase of Desulfovibrio vulgaris

The thiosulfate reductase of Desulfovibrio vulgaris has been purified and some of its properties have been determined. Only one protein component was detected when the purified enzyme was subjected to polyacrylamide gel electrophoresis at pH values of 8.9, 8.0, and 7.6. In the presence of H(2), the enzyme, when coupled to hydrogenase and with methyl viologen as an electron carrier, catalyzed the reduction of thiosulfate to hydogen sulfide. The use of specifically labeled (35)S-thiosulfate revealed that the outer sulfur atom was reduced to sulfide and the inner sulfur atom was released as sulfite. Thus, the enzyme catalyzes the reductive dismutation of thiosulfate to sulfide and sulfite. The molecular weight of the enzyme was determined by sedimentation equilibrium (16,300) and amino acid analysis (15,500). The enzyme sedimented as a single, symmetrical component with a calculated sedimentation coefficient of 2.21S. Amino acid analysis revealed the presence of two half-cystine residues per mole of enzyme and a total of 128 amino acid residues. Carbohydrate and organic phosphorus analyses revealed the presence of 9.2 moles of carbohydrate and 4.8 moles of phosphate per mole of enzyme. The substrate specificity of the enzyme was studied.     

The genomes of Desulfovibrio gigas and D. vulgaris

Two-dimensional electrophoresis of sequential double-restriction digests showed that the genome of Desulfovibrio gigas compromised 1.63 x 10(6) bp (1.09 x 10(9) Dal) of DNA; an ammonia-limited chemostat population possessed an average of nine genomes per cell and a multiplying batch culture possessed approximately 17 genomes per cell. The genome size of D. vulgaris (Hildenborough) was 1.72 x 10(6) bp (1.14 x 10(9) Dal); a population from an ammonia-limited batch culture contained four genomes per cell. Control digestions and analyses with Escherichia coli GM4 agreed reasonably with published values: a genome size of 3.95 x 10(6) bp and approximately two genomes per cell from a stationary batch culture in glucose minimal medium. Desulfovibrio gigas carried two plasmids of approximately 70 MDal (1.05 x 10(5) bp) and approximately 40 MDal (6 x 10(4) bp); D. vulgaris (Hildenborough) contained one of approximately 130 MDal (1.95 x 10(5) bp). Single plasmids were also detected in a second strain of D. vulgaris and in strain Berre sol of D. desulfuricans but not in 10 other desulfovibrios including representatives of D. desulfuricans, D. vulgaris, D. salexigens and D. africanus.     

Homology of Ribosomal Ribonucleic Acid of Desulfovibrio Species with Desulfovibrio vulgaris

Three species of Desulfovibrio were found to have a high degree of ribosomal ribonucleic acid homology with Desulfovibrio vulgaris. Desulfotomaculum nigrificans, which is also a sulfate-reducing anaerobe, had only 38% ribosomal ribonucleic acid homology with D. vulgaris. The homologies of six other unrelated genera were determined and found to be lower than 50%.     

Octomeric pyruvate-ferredoxin oxidoreductase from Desulfovibrio vulgaris

Pyruvate-ferredoxin oxidoreductatse (PFOR) carries out the central step in oxidative decarboxylation of pyruvate to acetyl-CoA. We have purified this enzyme from Desulfovibrio vulgaris Hildenborough (DvH) as part of a systematic characterization of as many multiprotein complexes as possible for this organism, and the three-dimensional structure of this enzyme has been determined by a combination of electron microscopy (EM), single particle image analysis, homology modeling and computational molecular docking. Our results show that the 1MDa DvH PFOR complex is a homo-octomer, or more precisely, a tetramer of the dimeric form of the related enzyme found in Desulfovibrio africanus (Da), with which it shares a sequence identity of 69%. Our homology model of the DvH PFOR dimer is based on the Da PFOR X-ray structure. Docking of this model into our 17A resolution EM-reconstruction of negatively stained DvH PFOR octomers strongly suggests that the difference in oligomerization state for the two species is due to the insertion of a single valine residue (Val383) within a surface loop of the DvH enzyme. This study demonstrates that the strategy of intermediate resolution EM reconstruction coupled to homology modeling and docking can be powerful enough to infer the functionality of single amino acid residues.     

Ferroxidase activity of recombinant Desulfovibrio vulgaris rubrerythrin

 Rubrerythrin (Rr) is the trivial name given to a non-heme iron protein of unknown function which has been found in anaerobic sulfate-reducing bacteria. Rr is unique in containing both rubredoxin-type FeS₄ and diiron-oxo sites in the same protein. The results described here demonstrate for the recombinant protein that: (a) Rr catalyzes oxidation of Fe²⁺ to Fe³⁺ by O₂, i.e., Rr has ferroxidase activity, (b) both FeS₄ and diiron domains of the Rr protein are required for ferroxidase activity, (c) with excess Fe²⁺ and O₂ the initial rate of this oxidation appears to be first order in [Rr] and independent of starting [Fe²⁺] above 30 μM, (d) the Fe³⁺ is produced in a form which is capable of rapid incorporation into the iron-binding site of ovotransferrin, and (e) the ferroxidase activity of Rr is comparable to that of published ferroxidase activities of apoferritins on a subunit basis. Ferroxidase activity of Rr was monitored either by the rate of increase in absorbance at 315 nm (which lies near an isosbestic point for oxidized and reduced Rr) or by using apoovotransferrin as Fe³⁺ acceptor, and measuring the rate and extent of diferric transferrin formation at 460 nm. No polyironoxyhydroxide aggregates appeared to associate with Rr after the ferroxidase reaction. A truncated form of Rr containing only the diiron domain had little or no ferroxidase activity. Rr could function as one component of a set of enzymes which channels the reaction products of O₂ and Fe²⁺ onto a non-toxic pathway during transient exposure of the bacteria to air.     

Morphology of bacteriophage-like particles from Desulfovibrio vulgaris

Phagelike particles obtained from a mitomycin C-induced lysate of Desulfovibrio vulgaris are described. Whether they can be classified as temperate bacteriophages or as bacteriocins has not been determined.     

Magnetic susceptibility of hydrogenase from Desulfovibrio vulgaris

Magnetization and magnetic susceptibility measurements revealed that the hydrogenase [EC 1.12.2.1] from Desulfovibrio vulgaris Miyazaki F has an independent unpaired electron in its iron-sulfur cluster. The paramagnetic center of the Desulfovibrio hydrogenase is, therefore, different from that in the Chromatium hydrogenase which interacts with another paramagnetic center, probably nickel.     

Carbon monoxide cycling by Desulfovibrio vulgaris Hildenborough

Sulfate-reducing bacteria, like Desulfovibrio vulgaris Hildenborough, use the reduction of sulfate as a sink for electrons liberated in oxidation reactions of organic substrates. The rate of the latter exceeds that of sulfate reduction at the onset of growth, causing a temporary accumulation of hydrogen and other fermentation products (the hydrogen or fermentation burst). In addition to hydrogen, D. vulgaris was found to produce significant amounts of carbon monoxide during the fermentation burst. With excess sulfate, the hyd mutant (lacking periplasmic Fe-only hydrogenase) and hmc mutant (lacking the membrane-bound, electron-transporting Hmc complex) strains produced increased amounts of hydrogen from lactate and formate compared to wild-type D. vulgaris during the fermentation burst. Both hydrogen and CO were produced from pyruvate, with the hyd mutant producing the largest transient amounts of CO. When grown with lactate and excess sulfate, the hyd mutant also exhibited a temporary pause in sulfate reduction at the start of stationary phase, resulting in production of 600 ppm of headspace hydrogen and 6,000 ppm of CO, which disappeared when sulfate reduction resumed. Cultures with an excess of the organic electron donor showed production of large amounts of hydrogen, but no CO, from lactate. Pyruvate fermentation was diverse, with the hmc mutant producing 75,000 ppm of hydrogen, the hyd mutant producing 4,000 ppm of CO, and the wild-type strain producing no significant amount of either as a fermentation end product. The wild type was most active in transient production of an organic acid intermediate, tentatively identified as fumarate, indicating increased formation of organic fermentation end products in the wild-type strain. These results suggest that alternative routes for pyruvate fermentation resulting in production of hydrogen or CO exist in D. vulgaris. The CO produced can be reoxidized through a CO dehydrogenase, the presence of which is indicated in the genome sequence.     

Cysteine synthesis by Desulfovibrio vulgaris extracts.

Extracts of Desulfovibrio vulgaris were found to contain serine transacetylase and cysteine synthase activities. When extracts were incubated with bisulfite and o-acetylserine, or acetyl coenzyme A plus L-serine, under a hydrogen atmosphere, cysteine was formed. Pyruvate served as a reductant for bisulfite reduction to sulfide and concomitantly provided the acetyl moiety for acetyl coenzyme A formation. Consequently, when extracts were incubated with pyruvate, bisulfite, and L-serine, cysteine synthesis resulted.     

Guanylcobamide and hypoxanthylcobamide-Corrinoids formed by Desulfovibrio vulgaris

The corrinoids synthesized by the sulfate-reducing bacterium Desulfovibrio vulgaris were analyzed. The compounds found were guanylcobamide and hypoxanthylcobamide; structures were determined by mass spectrometry, ¹H-NMR, and ultraviolet/visible spectroscopy. D. vulgaris used externally added guanine to form guanylcobamide, as demonstrated with 8-¹⁴C-guanine. Addition of adenine did not lead to the formation of adenylcobamide (pseudovitamin B₁₂), whereas 5,6-dimethylbenzimidazole was transformed into vitamin B₁₂.     

Physicochemical properties of flavodoxin from Desulfovibrio vulgaris.

Reductive titration curves of flavodoxin from Desulfovibrio vulgaris displayed two one-electron steps. The redox potential E-2 for the couple oxidized flavodoxin/flavodoxin semiquinone was determined by direct titration with dithionite. E-2 was -149 plus or minus 3 mV (pH 7.78, 25 degrees C). The redox potential E-1 for the couple flavodoxin semiquinone/fully reduced flavodoxin was deduced from the equilibrium concentration of these species in the presence of hydrogenase and H-2. E-1 was -438 plus or minus 8 mV (pH 7.78, 25 degrees C). Light-absorption and fluorescence spectra of flavodoxin in its three redox states have been recorded. Both the rate and extent of reduction of flavodoxin semiguinone with dithionite were found to depend on pH. An equilibrium between the semiquinone and hydroquinone forms occurred at pH values close to the neutrality, even in the presence of a large excess of dithionite, suggesting an ionization in fully reduced flavodoxin with a pK-a = 6.6. The association constants K for the three FMN redox forms with the apoprotein were deduced from the value of K (K = 8 times 10-7 M-1) measured with oxidized EMN at pH 7.0. Oxidized flavodoxin was found to comproportionate with the fully reduced protein (k-comp = 4.3 times 10-3 M-1 times s-1, pH 9.0, 22 degrees C) and with reduced free FMN (K-comp = 44 M-1 times s-1, pH 8.1, 20 degrees C). Fast oxidation of reduced flavodoxin occurred in the presence of O-2. Slower oxidation of semiquinone was dependent on pH in a drastic way.     

Dissimilatory reduction of bisulfite by Desulfovibrio vulgaris.

The reduction of bisulfite by Desulfovibrio vulgaris was investigated. Crude extracts reduced bisulfite to sulfide without the formation (detection) of any intermediates such as trithionate or thiosulfate. When the particulate fractions was removed from crude extracts by high-speed centrifugation, the soluble supernatant fraction reduced bisulfite sequentially to trithionate, thiosulfate, and sulfide. Addition of particles or purified membranes to the soluble fraction restored the original activity demonstrated by crude extracts, i.e., reduction of bisulfite to sulfide without the formation of trithionate and/or thiosulfate. By using antiserum directed against bisulfite reductase, the reduction of bisulfite by crude extracts was inhibited. This finding, in addition to several recycling studies of thiosulfate reduction, provided evidence that bisulfite reduction by D. vulgaris operated through the pathway involving trithionate and thiosulfate as intermediates. The role of membranes in this process is discussed.