Phosphorylation and phosphate-ATP exchange catalyzed by the ATP synthase isolated from Wolinella succinogenes

The ATP synthase, isolated from Wolinella (formerly Vibrio) succinogenes could be fully incorporated into liposomes without significant cleavage of the enzyme or loss of activity. These proteoliposomes, but not the isolated enzyme, catalyzed phosphate-ATP exchange and the phosphorylation of ADP which was driven by an artificially imposed delta mu H across the liposomal membrane. Phosphorylation driven by light was catalyzed by proteoliposomes containing also bacteriorhodopsin. The three activities were similarly sensitive to protonophores or dicyclohexylcarbodiimide. This sensitivity was similar to that of the electron-transport-driven phosphorylation catalyzed by bacterial membrane vesicles. With a delta mu H value 280 mV to drive phosphorylation the turnover number of the enzyme was in the same order of magnitude as that measured in the electron-transport-driven phosphorylation catalyzed by the bacterial membrane. When the delta mu H was below 150 mV, the phosphorylation activity of the incorporated enzyme was two orders of magnitude slower, and was about as fast as light-driven phosphorylation or as the exchange reaction.     

Flavodoxin from Wolinella succinogenes

A monomeric flavoprotein (18.8 kDa) was isolated from the soluble cell fraction of Wolinella succinogenes and was identified as a flavodoxin based on its N-terminal sequence, FMN content, and redox properties. The midpoint potentials of the flavodoxin (Fld) at pH 7.5 were measured as –95 mV (Fld_ox/Fld_s) and –450 mV (Fld_s/Fld_red) relative to the standard hydrogen electrode. The cellular flavodoxin content [0.3 μmol (g protein)^–1] was the same in bacteria grown with fumarate or with polysulfide as the terminal acceptor of electron transport. The flavodoxin did not accept electrons from hydrogenase or formate dehydrogenase, the donor enzymes of electron transport to fumarate or polysulfide. Pyruvate:flavodoxin oxidoreductase activity [180 U (g cellular protein)^–1] was detected in the soluble cell fraction of W. succinogenes grown with fumarate or polysulfide. The enzyme was equally active with Fld_ox or Fld_s at high concentrations. The K _m for Fld_s (80 μM) was larger than that for Fld_ox and for the ferredoxin isolated from W. succinogenes (15 μM). We conclude that flavodoxin serves anabolic rather than catabolic functions in W. succinogenes. Received: 15 May 1996 / Accepted: 21 June 1996     

Basal-body-associated disks are additional structural elements of the flagellar apparatus isolated from Wolinella succinogenes.

The intact flagella of Wolinella succinogenes, a gram-negative, anaerobic bacterium with a single polar flagellum, were obtained by an improved procedure, introduced recently by Aizawa et al. (S.-J. Aizawa, G. E. Dean, C. J. Jones, R. M. Macnab, and S. Yamaguchi, J. Bacteriol. 161:836-849, 1985) for the flagellum of Salmonella typhimurium. Disks with a diameter of 130 +/- 30 nm, which were attached to the basal body of the isolated intact flagella, could be identified by electron microscopy as additional structural elements of the bacterial flagellar apparatus. In freeze-dried and metal-shadowed samples, two rings of the basal body were detected on one side and a terminal knob was located on the other side of the disks. Suspension of the flagellar apparatus in acidic solution dissociated the flagellar filaments, yielding hook-basal body complexes with and without the associated disks. If whole cells were subjected to low pH, double disks of the same diameter and with a central hole of about 13 nm could be isolated. Similar parallel disks could be seen also in negatively stained whole cells. When uranyl acetate was used for negative staining of the intact flagella, concentric rings were detected on the disks, similar to the concentric membrane rings found by Coulton and Murray (J. W. Coulton and R. G. E. Murray, J. Bacteriol. 136:1037-1049, 1978) on platelike arrays of proteins in outer membrane preparations of Aquaspirillum serpens. Because the disks of W. succinogenes can be isolated together with the flagellar hook-basal body complex, they appear to be basal-body-rather than secondary membrane-associated structures. It is possible that these disks are the bearing or stator of this rotary device.     

Production, characterization and determination of the real catalytic properties of the putative 'succinate dehydrogenase' from Wolinella succinogenes

Both the genomes of the epsilonproteobacteria Wolinella succinogenes and Campylobacter jejuni contain operons ( sdhABE ) that encode for so far uncharacterized enzyme complexes annotated as 'non-classical' succinate:quinone reductases (SQRs). However, the role of such an enzyme ostensibly involved in aerobic respiration in an anaerobic organism such as W. succinogenes has hitherto been unknown. We have established the first genetic system for the manipulation and production of a member of the non-classical succinate:quinone oxidoreductase family. Biochemical characterization of the W. succinogenes enzyme reveals that the putative SQR is in fact a novel methylmenaquinol:fumarate reductase (MFR) with no detectable succinate oxidation activity, clearly indicative of its involvement in anaerobic metabolism. We demonstrate that the hydrophilic subunits of the MFR complex are, in contrast to all other previously characterized members of the superfamily, exported into the periplasm via the twin-arginine translocation (tat)-pathway. Furthermore we show that a single amino acid exchange (Ala86→His) in the flavoprotein of that enzyme complex is the only additional requirement for the covalent binding of the otherwise non-covalently bound FAD. Our results provide an explanation for the previously published puzzling observation that the C. jejuni sdhABE operon is upregulated in an oxygen-limited environment as compared with microaerophilic laboratory conditions.     

Reconstitution of coupled fumarate respiration in liposomes by incorporating the electron transport enzymes isolated from Wolinella succinogenes.

Hydrogenase and fumarate reductase isolated from Wolinella succinogenes were incorporated into liposomes containing menaquinone. The two enzymes were found to be oriented solely to the outside of the resulting proteoliposomes. The proteoliposomes catalyzed fumarate reduction by H2 which generated an electrical proton potential (Delta(psi) = 0.19 V, negative inside) in the same direction as that generated by fumarate respiration in cells of W. succinogenes. The H+/e ratio brought about by fumarate reduction with H2 in proteoliposomes in the presence of valinomycin and external K+ was approximately 1. The same Delta(psi) and H+/e ratio was associated with the reduction of 2,3-dimethyl-1,4-naphthoquinone (DMN) by H2 in proteoliposomes containing menaquinone and hydrogenase with or without fumarate reductase. Proteoliposomes containing menaquinone and fumarate reductase with or without hydrogenase catalyzed fumarate reduction by DMNH2 which did not generate a Delta(psi). Incorporation of formate dehydrogenase together with fumarate reductase and menaquinone resulted in proteoliposomes catalyzing the reduction of fumarate or DMN by formate. Both reactions generated a Delta(psi) of 0.13 V (negative inside). The H+/e ratio of formate oxidation by menaquinone or DMN was close to 1. The results demonstrate for the first time that coupled fumarate respiration can be restored in liposomes using the well characterized electron transport enzymes isolated from W. succinogenes. The results support the view that Delta(psi) generation is coupled to menaquinone reduction by H2 or formate, but not to menaquinol oxidation by fumarate. Delta(psi) generation is probably caused by proton uptake from the cytoplasmic side of the membrane during menaquinone reduction, and by the coupled release of protons from H2 or formate oxidation on the periplasmic side. This mechanism is supported by the properties of two hydrogenase mutants of W. succinogenes which indicate that the site of quinone reduction is close to the cytoplasmic surface of the membrane.     

Solution structure of the 30 kDa polysulfide-sulfur transferase homodimer from Wolinella succinogenes

The periplasmic polysulfide-sulfur transferase (Sud) protein encoded by Wolinella succinogenes is involved in oxidative phosphorylation with polysulfide-sulfur as a terminal electron acceptor. The polysulfide-sulfur is covalently bound to the catalytic Cys residue of the Sud protein and transferred to the active site of the membranous polysulfide reductase. The solution structure of the homodimeric Sud protein has been determined using heteronuclear multidimensional NMR techniques. The structure is based on NOE-derived distance restraints, backbone hydrogen bonds, and torsion angle restraints as well as residual dipolar coupling restraints for a refinement of the relative orientation of the monomer units. The monomer structure consists of a five-stranded parallel beta-sheet enclosing a hydrophobic core, a two-stranded antiparallel beta-sheet, and six alpha-helices. The dimer fold is stabilized by hydrophobic residues and ion pairs found in the contact area between the two monomers. Similar to rhodanese enzymes, Sud catalyzes the transfer of the polysulfide-sulfur to the artificial acceptor cyanide. Despite their similar functions and active sites, the amino acid sequences and structures of these proteins are quite different.     

Menaquinone-6 and thermoplasmaquinone-6 in Wolinella succinogenes

Abstract The respiratory quinone composition of Wolinella succinogenes was investigated. Unsaturated menaquinones with six isoprene units (2-methyl-3-hexaprenyl-1,4-naphthoquinone) was found to be the major isoprenoid quinone. Substantial levels of a methyl-substituted menaquinone was also present. Mass spectrometry and proton nuclear magnetic resonance spectrometry indicated the methyl-substituted quinone corresponded to 2-, [5 or 8]- dimethyl-3-hexaprenyl-1,4-naphthoquinone.     

The purification and some equilibrium properties of the nitrite reductase of the bacterium Wolinella succinogenes.

The bacterium Wolinella succinogenes produces a nitrite reductase enzyme that can be purified to homogeneity in high yield by a combination of detergent extraction, hydroxyapatite chromatography and Mr fractionation. Nitrite reductase activity is found to be present in both a high- and a low-Mr fraction. The high-Mr fraction has been shown to consist of the low-Mr nitrite reductase enzyme associated with a hydrophobic 'binding protein'. The amino acid composition for both proteins is reported. The nitrite reductase enzyme shows spectral characteristics indicative of the presence of c-type haem groups. Measurements at 610 nm indicate the presence of some high-spin haem groups at neutral pH. This haem subgroup undergoes a pH-linked high-spin - low-spin transition at alkaline pH. Approximately two of the six haem groups present within the enzyme bind CO with low affinity (KD = 0.4 mM). The enzyme also shows a range of redox activities with various inorganic reagents. The enzyme has been shown to exhibit dithionite reductase, oxygen reductase and CO2 reductase activities.     

Comparative EPR studies on the nitrite reductases from Escherichia coli and Wolinella succinogenes

Hexaheme nitrite reductases purified to homogeneity from Escherichia coli K-12 and Wolinella succinogenes were studied by low-temperature EPR spectroscopy. In their isolated states, the two enzymes revealed nearly identical EPR spectra when measured at 12 K. Both high-spin and low-spin ferric heme EPR resonances with g values of 9.7, 3.7, 2.9, 2.3 and 1.5 were observed. These signals disappeared upon reduction by dithionite. Reaction of reduced enzyme with nitrite resulted in the formation of ferrous heme-NO complexes with distinct EPR spectral characteristics. The heme-NO complexes formed with the two enzymes differed, however, in g values and line-shapes. When reacted with hydroxylamine, reduced enzymes also showed the formation of ferrous heme-NO complexes. These results suggested the involvement of an enzyme-bound NO intermediate during the six-electron reduction of nitrite to ammonia catalyzed by these two hexaheme nitrite reductases. Heme proteins that can either expose bound NO to reduction or release it are significant components of both assimilatory and dissimilatory metabolisms of nitrate. The different ferrous heme-NO complexes detected for the two enzymes indicated, nevertheless, their subtle variation in heme reactivity during the reduction reaction.     

DMSO respiration by the anaerobic rumen bacterium Wolinella succinogenes

The anaerobic rumen bacterium Wolinella succinogenes was able to grow by respiration with dimethylsulphoxide (DMSO) as electron acceptor and formate or H₂ as electron donors. The growth yield amounted to 6.7 g and 6.4 g dry cells/mol DMSO with formate or H₂ as the donors, respectively. This suggested an ATP yield of about 0.7 mol ATP/mol DMSO. Cell homogenates and the membrane fraction contained DMSO reductase activity with a high K _m (43 mM) for DMSO. The electron transport from H₂ to DMSO in the membranes was inhibited by 2-(heptyl)-4-hydroxyquinoline N-oxide, indicating the participation of menaquinone. Formation of DMSO reductase activity occurred only during growth on DMSO, presence of other electron acceptors (fumarate, nitrate, nitrite, N₂O, and sulphur) repressed the DMSO reductase activity. DMSO can therefore be used by W. succinogenes as an acceptor for phosphorylative electron transport, but other electron acceptors are used preferentially.Abbreviations DMN 2,3-Dimethyl-1,4-naphthoquinone - DMNH ₂ Reduced DMN - DMS Dimethylsulphide (CH₃)₂S - DMSO Dimethylsulphoxide (CH₃)₂SO - HQNO 2-(Heptyl)-4-hydroxyquinoline-N-oxide - TMAO Trimethylamine-N-oxide - Y _s Growth yield for substrate S     

Cloning and expression of the genes of two fumarate reductase subunits from Wolinella succinogenes

The fumarate reductase complex of the anaerobic bacterium Wolinella succinogenes catalyzes the electron transfer from menaquinol to fumarate. Two structural genes coding for subunits of the enzyme have been cloned in Escherichia coli. The genes were isolated from a lambda EMBL3 phage gene bank by immunological screening and subcloned in an expression vector. The genes frdA and frdB, which encode the FAD protein (Frd A, Mr 79,000) and the iron-sulfur protein (Frd B, Mr 31,000) of the fumarate reductase complex, were cloned together with a W. succinogenes promoter. The gene order was promoter-frdA-frdB. The FAD protein and the iron-sulfur protein were expressed in the correct molar mass in E. coli from the clones. The identity of the frdA gene and the suggested polarity were confirmed by comparing the amino-terminal sequence of the Frd A protein with that predicted from the 5'-terminal nucleotide sequence of frdA. The frdA and frdB genes are present only once in the genome. A region downstream of frdB, possibly a gene encoding cytochrome b of the fumarate reductase complex, hybridizes with a second site in the genome.     

Polysulfide reductase and formate dehydrogenase from Wolinella succinogenes contain molybdopterin guanine dinucleotide

Pterin derivatives were extracted from formate dehydrogenase and from polysulfide reductase of Wolinella succinogenes and converted to 6-carboxypterin. The amounts of 6-carboxypterin were consisted with the molybdenum content of the enzymes. The bis(carboxamidomethyl) derivatives of the cofactors showed absorption spectra that were identical with that of the corresponding molybdopterin guanine dinucleotide derivative (cam MGD). After hydrolysis of the derivatives with nucleotide pyrophosphatase in the presence of alkaline phosphatase, guanosine was formed together with a compound showing the properties of dephospho-bis(carboxamidomethyl)-molybdopterin. It is conluded that both formate dehydrogenase and polysulfide reductase of W. succinogenes contain molybdopterin guanine dinucleotide.Abbreviations MPT molybdopterin - MGD molybdopterin guanine dinucleotide - cam MPT bis(carboxyamidomethyl)-molybdopterin - cam MGD bis(carboxyamidomethyl)-molybdopterin guanine dinucleotide     

Kinetic studies on the nitrite reductase of Wolinella succinogenes.

Calibration relationships were derived for cartilage proteoglycan subunit (PGS) that relate the inverse z-average hydrodynamic radius (Rs) and the weight-average Mr (Mw) to the partition coefficient (Kav.) for PGS when chromatographed on a Sepharose CL-2B column. PGS isolated from chick limb-bud chondrocyte cell cultures was fractionated chromatographically into eight pools, for which Mw and Rs were determined by total-intensity and dynamic light-scattering measurements. These data were found to be related to Kav. through the following empirical equations: log Mw = -(1.65 +/- 0.27)Kav. +(6.58 +/- 0.08); log Rs = -(0.69 +/- 0.04)Kav. +(2.75 +/- 0.01). Application of these relationships to the chromatographic data led to Mw = 1.48 X 10(6) and Rs = 38.7 nm (387 A) for the unfractionated specimens compared with values of Mw = 1.46 X 10(6) and Rs = 38.2 nm (382 A) determined by light-scattering. Our results were found to be consistent with previously proposed phenomenological models for the gel-filtration mechanism. Application of these calibration relationships to Kav. for several unfractionated specimens led to predicted values of Mw and Rs that are accurate to within 10%.     

16S rRNA analysis and the phylogenetic position of Wolinella succinogenes

The 16S ribosomal RNA of Wolinella succinogenes ATCC29543 was analyzed by the RNase T1 oligonucleotide cataloguing approach. In contrast to its present classification, W. succinogenes is related neither to members of the genus Bacteroides nor to any other genus of the family Bacteroidaceae. As derived from the similarity coefficients (S_AB values) calculated on the basis of more than 350 eubacterial species, W. succinogenes appears to be a distantly related member of the division of purple photosynthetic bacteria and their relatives; however, S_AB values do not indicate that this species is preferentially related to any representative of the 4 subdivisions.     

Purification and some characteristics of a cytochrome c-containing nitrous oxide reductase from Wolinella succinogenes

Nitrous oxide reductase from Wolinella succinogenes was purified very nearly to homogeneity. The enzyme was found to be dimeric, with Mr = 162,000 and subunit Mr = 88,000, and to contain three copper atoms and one iron atom (as cytochrome c) per subunit. The oxidized enzyme exhibited absorption bands at 410 and 528 nm, and the dithionite-reduced enzyme, at 416, 520, and 550 nm. The isoelectric point was 8.6; specific activity was at 25 degrees C and pH 7.1, 160 mumol x min-1 x mg-1; and Km was 7.5 microM N2O under the same conditions. alpha-Chymotrypsin cleaved the enzyme into cytochrome c-depleted dimers with an average Mr = 134,000 and cytochrome c-enriched fragments with an average Mr = 13,000. The enzyme was stable at 4 degrees C for at least 100 h under air and 3 h in the presence of 5 mM EDTA. It exhibited a dithionite-N2O oxidoreductase as well as a BV+-N2O oxidoreductase activity. During turnover with BV+ at 25 mM N2O, the enzyme was observed to undergo an initial activation and a subsequent inactivation. The kinetics of inactivation were approximately first-order in remaining activity, and the first-order rate constant was essentially independent of the initial enzyme concentration. These characteristics are consistent with the occurrence of turnover-dependent inactivation. Acetylene was a relatively weak inhibitor, but cyanide and azide were rather strong inhibitors. The nitrous oxide reductase of W. succinogenes is quite different from that of denitrifying bacteria. The amount of activity in cell extracts and the absence of O2-labile nitrous oxide reductase suggested that the cytochrome c containing enzyme may be the only one produced by W. succinogenes.     

Structural organization of mitochondrial ATP synthase

Specific modules and subcomplexes like F(1) and F(0)-parts, F(1)-c subcomplexes, peripheral and central stalks, and the rotor part comprising a ring of c-subunits with attached subunits gamma, delta, and epsilon can be identified in yeast and mammalian ATP synthase. Four subunits, alpha(3)beta(3), OSCP, and h, seem to form a structural entity at the extramembranous rotor/stator interface (gamma/alpha(3)beta(3)) to hold and stabilize the rotor in the holo-enzyme. The intramembranous rotor/stator interface (c-ring/a-subunit) must be dynamic to guarantee unhindered rotation. Unexpectedly, a c(10)a-assembly could be isolated with almost quantitive yield suggesting that an intermediate step in the rotating mechanism was frozen under the conditions used. Isolation of dimeric a-subunit and (c(10))(2)a(2)-complex from dimeric ATP synthase suggested that the a-subunit stabilizes the same monomer-monomer interface that had been shown to involve also subunits e, g, b, i, and h. The natural inhibitor protein Inh1 does not favor oligomerization of yeast ATP synthase. Other candidates for the oligomerization of dimeric ATP synthase building blocks are discussed, e.g. the transporters for inorganic phosphate and ADP/ATP that had been identified as constituents of ATP synthasomes. Independent approaches are presented that support previous reports on the existence of ATP synthasomes in the mitochondrial membrane.     

Nitrogen oxide reduction in Wolinella succinogenes and Campylobacter species.

Wolinella succinogenes cells and extracts reduced nitric oxide, and cells, but not extracts, reduced nitrous oxide. Formate-reduced W. succinogenes extracts generated the 573-nm peak in difference spectra seen previously in response to nitric oxide in denitrifiers. The type strains of several Campylobacter species did not reduce either gaseous oxide. Cells, but not extracts, of C. fetus subspecies (fetus and venerealis) reduced nitrous oxide; acetylene inhibited reduction. Neither cells nor extracts reduced nitric oxide.