The electrochemical proton potential generated by the sulphur respiration of Wolinella succinogenes

Wolinella succinogenes grown on formate and elemental sulphur was found to use the polysulphide derivatives 2,2-tetrathiobispropionate (R₂S₄) or pentathionate (S₅O ₆ ⁼ ) as acceptors for formate oxidation. The specific activities of formate oxidation with these acceptors were similar to those with elemental sulphur. The main reaction products of R₂S₄ reduction were 2,2-dithiobispropionate (R₂S₂) and sulphide. Pentathionate was converted to thiosulphate and some elemental sulphur. The electrochemical proton potential across the cytoplasmic membrane of the bacterium was measured in the steady state of electron transport from formate to R₂S₄. The electrical proportion () of the determined through the distribution of labeled tetraphenylphosphonium cation was obtained as 0.17 Volt. The was zero, when a protonophore was present. The pH-difference across the membrane was negligible. Thus the generated by sulphur respiration is close to that measured earlier with fumarate as the terminal acceptor of electron transport.Abbreviations DMO 5,5-dimethyloxazolidine-2,4-dione - R₂S_n (n=2–5) 2,2-polythiobispropionate - TTFB 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidazol - TPP tetraphenylphosphonium cation     

Regulation of anaerobic respiratory pathways in Wolinella succinogenes by the presence of electron acceptors

In Wolinella succinogenes ATP synthesis and consequently bacterial growth can be driven by the reduction of either nitrate (E₀=+0.42 V), nitrite (E₀=+0.36 V), fumarate (E₀=+0.03 V) or sulphur (E₀=-0.27 V) with formate as the electron donor. Bacteria growing in the presence of nitrate and fumarate were found to reduce both acceptors simultaneously, while the reduction of both nitrate and fumarate is blocked during growth with sulphur. These observations were paralleled by the presence and absence of the corresponding bacterial reductase activities. Using a specific antiserum, fumarate reductase was shown to be present in bacteria grown with fumarate and nitrate, and to be nearly absent from bacteria grown in the presence of sulphur. The contents of polysulphide reductase, too, corresponded to the enzyme activities found in the bacteria. This suggests that the activities of anaerobic respiration are regulated at the biosynthetic level in W. succinogenes. Thus nitrate and fumarate reduction are repressed by the most electronegative acceptor of anacrobic respiration, sulphur. By contrast, in Escherichia coli a similar effect is exerted by the most electropositive acceptor, O₂. W. succinogenes also differs from E. coli in that fumarate reductase is not repressed by nitrate.Abbreviations BV benzyl viologen - DMN 2,3-dimethyl-1,4-naphthoquinone - DMSO dimethylsulfoxide - TMAO trimethylamine-N-oxide     

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     

Phorphorylative electron transport chains lacking a cytochromebc 1 complex

Electron transport-coupled phosphorylation with fumarate as terminal acceptor inWolinella succinogenes yields less than 1 ATP/2 electrons. The generated by the electron transport is 0.18V and the H⁺/electron ratio is 1. The electron transport chain is made up of two dehydrogenases (hydrogenase and formate dehydrogenase) that catalyze the reduction of menaquinone, and fumarate reductase which catalyzes the oxidation of menaquinol.C-type cytochromes are not involved. The phosphorylative electron transport with sulfur as terminal acceptor inW. succinogenes orDesulfuromonas acetoxidans does not involve known quinones. The ATP yields should be even smaller than those with fumarate. Succinate oxidation by sulfur, which is a catabolic reaction inD. acetoxidans, is accomplished by reversed electron transport.     

Low-potential cytochrome b as an essential electron-transport component of menaquinone reduction by formate in Vibrio succinogenes

Incorporation of the electron-transport enzymes of Vibrio succinogenes into liposomes was used to investigate the question of whether, in this organism, a cytochrome b is involved in electron transport from formate to fumarate on the formate side of menaquinone. (1) Formate dehydrogenase lacking cytochrome b was prepared by splitting the cytochrome from the formate dehydrogenase complex. The enzyme consisted of two different subunits (M_r 110 000 and 20 000), catalyzed the reduction of 2,3-dimethyl-1,4-naphthoquinone by formate, and could be incorporated into liposomes. (2) The modified enzyme did not restore electron transport from formate to fumarate when incorporated into liposomes together with vitamin K-1 (instead of menaquinone) and fumarate reductase complex. In contrast, restoration was observed in liposomes that contained formate dehydrogenase with cytochrome b (E_m = ?224 mV), in addition to the subunits mentioned above (formate dehydrogenase complex). (3) In the liposomes containing formate dehydrogenase complex and fumarate reductase complex, the response of the cytochrome b of the formate dehydrogenase complex was consistent with its interaction on the formate side of menaquinone in a linear sequence of the components. The low-potential cytochrome b associated with fumarate reductase complex was not reducible by formate under any condition. It is concluded that the low-potential cytochrome b of the formate dehydrogenase complex is an essential component in the electron transport from formate to menaquinone. The low-potential cytochrome b of the fumarate reductase complex could not replace the former cytochrome in restoring electron-transport activity.     

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     

Investigation of the fumarate metabolism of the syntrophic propionate-oxidizing bacterium strain MPOB

The growth of the syntrophic propionate-oxidizing bacterium strain MPOB in pure culture by fumarate disproportionation into carbon dioxide and succinate and by fumarate reduction with propionate, formate or hydrogen as electron donor was studied. The highest growth yield, 12.2 g dry cells/mol fumarate, was observed for growth by fumarate disproportionation. In the presence of hydrogen, formate or propionate, the growth yield was more than twice as low: 4.8, 4.6, and 5.2 g dry cells/mol fumarate, respectively. The location of enzymes that are involved in the electron transport chain during fumarate reduction in strain MPOB was analyzed. Fumarate reductase, succinate dehydrogenase, and ATPase were membrane-bound, while formate dehydrogenase and hydrogenase were loosely attached to the periplasmic side of the membrane. The cells contained cytochrome c, cytochrome b, menaquinone-6 and menaquinone-7 as possible electron carriers. Fumarate reduction with hydrogen in membranes of strain MPOB was inhibited by 2-(heptyl)-4-hydroxyquinoline-N-oxide (HOQNO). This inhibition, together with the activity of fumarate reductase with reduced 2,3-dimethyl-1,4-naphtoquinone (DMNH₂) and the observation that cytochrome b of strain MPOB was oxidized by fumarate, suggested that menequinone and cytochrome b are involved in the electron transport during fumarate reduction in strain MPOB. The growth yields of fumarate reduction with hydrogen or formate as electron donor were similar to the growth yield of Wolinella succinogenes. Therefore, it can be assumed that strain MPOB gains the same amount of ATP from fumarate reduction as W. succinogenes, i.e. 0.7 mol ATP/mol fumarate. This value supports the hypothesis that syntrophic propionate-oxidizing bacteria have to invest two-thirds of an ATP via reversed electron transport in the succinate oxidation step during the oxidation of propionate. The same electron transport chain that is involved in fumarate reduction may operate in the reversed direction to drive the energetically unfavourable oxidation of succinate during syntrophic propionate oxidation since (1) cytochrome b was reduced by succinate and (2) succinate oxidation was similarly inhibited by HOQNO as fumarate reduction. Received: 18 March 1997 / Accepted: 10 November 1997     

Properties of a Wolinella succinogenes mutant lacking periplasmic sulfide dehydrogenase (Sud)

A Δsud deletion mutant of Wolinella succinogenes that lacked the periplasmic sulfide dehydrogenase (Sud) was constructed using homologous recombination. The mutant grew with sulfide and fumarate, indicating that Sud was not a component of the electron transport chain that catalyzed fumarate respiration with sulfide as an electron donor. Likewise, growth with formate and either polysulfide or sulfur was not affected by the deletion. Removal of Sud from wild-type W. succinogenes by spheroplast formation did not decrease the activity of electron transport to polysulfide. The Δpsr deletion mutant that lacks polysulfide reductase (Psr) grew by fumarate respiration with sulfide as an electron donor, indicating that Psr is not required for this activity. Received: 31 August 1995 / Accepted: 25 October 1995     

Characterization of the NADH dehydrogenase and fumarate reductase of Fibrobacter succinogenes subsp. succinogenes S85

Conditions promoting maximal in vitro activity of the particulate NADH:fumarate reductase from Fibrobacter succinogenes were determined. This system showed a pH optimum of 6.0 in K⁺ MES buffer only when salt (NaCl or KCl) was present. Salt stimulated the activity eightfold at the optimal concentration of 150m M. This effect was due to stimulation of fumarate reductase activity as salt had little effect on NADH: decylubiquinone oxidoreductase (NADH dehydrogenase). The stimulation of fumarate reductase by salt at pH 6.0 was not due to removal of oxaloacetate from the enzyme. Kinetic parameters for several inhibitors were also measured. NADH dehydrogenase was inhibited by rotenone at a single site with a K _i of 1 M. 2-Heptyl-4-hydroxyquinonline-N-oxide (HOQNO) inhibited NADH: fumarate reductase with a K _i of 0.006 M, but NADH dehydrogenase exhibited two HOQNO inhibition constants of approximately 1 M and 24 M. Capsaicin and laurylgallate each inhibited NADH dehydrogenase by only 20% at 100 M. NADH dehydrogenase gave K _m values of 1 M for NADH and 4 M for reduced hypoxanthine adenine dinucleotide.Published with the approval of the Director of the Agricultural Experiment Station, North Dakota State University, as journal article no. 2201     

Growth of Wolinella succinogenes with polysulphide as terminal acceptor of phosphorylative electron transport

Polysulphide was formed according to reaction (1), when tetrathionate was (1) $${\text{S}}_4 {\text{O}}_6^{2 - } + {\text{HS}}^ - \to 2{\text{S}}_2 {\text{O}}_3^{2 - } + {\text{S(O)}} + {\text{H}}^ + $$ added to an anaerobic buffer (pH 8.5) containing excess sulphide. S(O) denotes the zero oxidation state sulphur in the polysulphide mixture S _infn ^sup2- . The addition of formate to the polysulphide solution in the presence of Wolinella succinogenes caused the reduction of polysulphide according to reaction (2). The bacteria grew in a medium containing formate and sulphide, (2) $${\text{HCO}}_2^ - + {\text{S(O)}} + {\text{H}}2{\text{O}} \to {\text{HCO}}_3^ - + {\text{HS}}^ - + {\text{H}}^ + $$ when tetrathionate was continuously added. The cell density increased proportional to reaction (3) which represents the sum of reactions (1) and (3) $${\text{HCO}}_2^ - + {\text{S}}_{\text{4}} {\text{O}}_6^{2 - } + {\text{H}}2{\text{O}} \to {\text{HCO}}_3^ - + 2{\text{S}}_{\text{2}} {\text{O}}_3^{2 - } + 2{\text{H}}^ + $$ (2). The cell yield per mol formate was nearly the same as during growth on formate and elemental sulphur, while the velocity of growth was greater. The specific activities of polysulphide reduction by formate measured with bacteria grown with tetrathionate or with elemental sulphur were consistent with the growth parameters. The results suggest that W. succinogenes grow at the expense of formate oxidation by polysulphide and that polysulphide is an intermediate during growth on formate and elemental sulphur.     

Reconstitution in liposomes of the electron-transport chain catalyzing fumarate reduction by formate

Fumarate reduction by formate in Vibrio succinogenes is catalyzed by a membrane-bound electron-transport chain, and is coupled with the phosphorylation of ADP. The electron-transport chain was reconstituted in liposomes from the isolated components. The formate dehydrogenase complex (three different peptides), the fumarate reductase complex (three different peptides) and vitamin K-1 were required for the electron transport. The pathway of the electrons from formate to fumarate in the reconstituted chain was identical with that in the bacterial membrane. Each of the active enzyme complexes in the liposomes participated in the electron transport. This was valid for proteoliposomes with ratios of the contents of the two enzyme complexes ranging between 0.1 and 10. This indicates that vitamin K-1 forms a diffusible pool within the liposomal membrane that allows every quinone molecule to react with each molecule of the two enzyme complexes.     

Effects of molybdenum and tungsten on induction of nitrate reductase and formate dehydrogenase in wild type and mutant Paracoccus denitrificans

Molybdenum is required for induction of nitrate reductase and of NAD-linked formate dehydrogenase activities in suspensions of wild type Paracoccus denitrificans; tungsten prevents the development of these enzyme activities. The wild type forms a membrane protein M _r150,000 when incubated with tungsten and inducers of nitrate reductase and this is presumed to represent an inactive form of the enzyme. Suspensions of mutant M-1 did not develop nitrate reductase or formate dehydrogenase activities but the membrane protein M _r150,000 was formed under all conditions tested, including without inducers and without molybdenum. Analysis of membranes, solubilized with deoxycholate, by polyacrylamide gel electrophoresis under nondenaturing conditions showed that the mutant protein had similar electrophoretic mobility to the active nitrate reductase formed by the wilde type. Autoradiography of preparations from cells incubated with ⁵⁵Fe showed that the mutant and wild type proteins contained iron. However, in similar experiments with ⁹⁹Mo, incorporation of molybdenum into the mutant protein was not detectable.We conclude that mutant M-1 is defective in one or more steps required to process molybdenum for incorporation into molybdoenzymes. This failure affects the normal regulation of nitrate reductase protein with respect to the role of inducers.Non-Standard Abbreviations DOC deoxycholate - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate     

The linear oxidation of formaldehyde to CO2 as the proper energy generating sequence for the assimilation of methanol in Acetobacter methanolicus MB58

Acetobacter methanolicus MB58 can grow on methanol. Since this substrate exhibits to be energy deficient there must be a chance to oxidize methanol to CO₂ merely for purpose of energy generation. For the assimilation of methanol the FBP variant of the RuMP pathway is used. Hence methanol can be oxidized cyclically via 6-phosphogluconate. Since Acetobacter methanolicus MB58 possesses all enzymes for a linear oxidation via formate the question arises which of both sequences is responsible for generation of the energy required. In order to clarify this the linear sequence was blocked by inhibiting the formate dehydrogenase with hypophosphite and by mutagenesis inducing mutants defective in formaldehyde or formate dehydrogenase. It has been shown that the linear dissimilatory sequence is indispensable for methylotrophic growth. Although the cyclic oxidation of formaldehyde to CO₂ has not been influenced by hypophosphite and with mutants both the wild type and the formaldehyde dehydrogenase defect mutants cannot grown on methanol. The cyclic oxidation of formaldehyde does not seem to be coupled to a sufficient energy generation, probably it operates only detoxifying and provides reducing equivalents for syntheses. The regulation between assimilation and dissimilation of formaldehyde in Acetobacter methanolicus MB58 is discussed.Abbreviations ATP Adenosine-5-triphosphate - DCPIP 2,6-dichlorphenolindophenol - DW dry weight - ETP electron transport phosphorylation - FBP fructose-1,6-bisphosphate - MNNG N-methyl-N-nitro-N-nitrosoguanidine - PMS phenazine methosulfate - RuMP ribulose monophosphate - Ru5P ribulose-5-phosphate - SDS sodiumdodecylsulphate - TCA tricarboxylic acid - TYB toluylene blue Dedicated to Prof. Dr. Dr. S. M. Rapoport on occasion of his 75th birthday     

Sulfide-quinone and sulfide-cytochrome reduction in Rhodobacter capsulatus

The reduction by sulfide of exogenous ubiquinone is compared to the reduction of cytochromes in chromatophores of Rhodobacter capsulatus. From titrations with sulfide values for V_max of 300 and 10 moles reduced/mg bacteriochlorophyll a·h, and for K_m of 5 and 3 M were estimated, for decyl-ubiquinone-and cytochrome c-reduction, respectively. Both reactions are sensitive to KCN, as has been found for sulfide-quinone reductase (SQR) in Oscillatoria limnetica, which is a flavoprotein. Effects of inhibitors interfering with quinone binding sites suggest that at least part of the electron transport from sulfide in R. capsulatus employs the cytochrome bc ₁-complex via the ubiquinone pool.Abbreviations BChl a bacteriochlorophyll a - DAD diaminodurene - decyl-UQ decyl-ubiquinone - LED light emitting diode - NQNO 2-n-nonyl-4-hydroxyquinoline-N-oxide - PQ-1 plastoquinone 1 - SQR sulfide-quinone reductase (E.C. 1.8.5.'.) - UQ ubiquinone 10 - Q_c the quinone reduction site on the cytochrome b ₆ f/bc ₁, complex (also termed Q_i or Q_r or Q_n) - Q_s the quinone reduction site on SQR - Q_z quinol oxidation site on the b ₆ f/bc ₁, complex (also termed Q_o or Q_p)     

Photosystem I cyclic electron transport: Measurement of ferredoxin-plastoquinone reductase activity

Absorbance changes of ferredoxin measured at 463 nm in isolated thylakoids were shown to arise from the activity of the enzyme ferredoxin-plastoquinone reductase (FQR) in cyclic electron transport. Under anaerobic conditions in the presence of DCMU and an appropriate concentration of reduced ferredoxin, a light-induced absorbance decrease due to further reduction of Fd was assigned to the oxidation of the other components in the cyclic pathway, primarily plastoquinone. When the light was turned off, Fd was reoxidised and this gave a direct quantitative measurement of the rate of cyclic electron transport due to the activity of FQR. This activity was sensitive to the classical inhibitor of cyclic electron transport, antimycin, and also to J820 and DBMIB. Antimycin had no effect on Fd reduction although this was inhibited by stigmatellin. This provides further evidence that there is a quinone reduction site outside the cytochrome bf complex. The effect of inhibitors of ferredoxin-NADP⁺ reductase and experiments involving the modification of ferredoxin suggest that there may be some role for the reductase as a component of FQR. Contrary to expectations, NADPH₂ inhibited FQR activity; ATP and ADP had no effect.Abbreviations AQS 9,10-anthraquinone-2-sulphonate - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethyl urea - dimaleimide N,N-p-phenylenedimaleimide - EDC N-(dimethylaminopropyl)-N-ethylcarbodiimide - Fd ferredoxin - FNR Fd-NADP⁺ oxidoreductase - FQR Fd-PQ reductase - GME glycine methyl ester - J820 tetrabromo-4-hydroxypyridine - PC plastocyanin - PMS N-methylphenazinium methyl sulphate - PS Photosystems I and II - PQ plastoquinone - Q quinone - Q_r and Q_o sites of quinone reduction and oxidation, respectively - sulpho-DSPD disulphodisalicylidenepropane-1,2-diamine     

The membraneous nitrite reductase involved in the electron transport of Wolinella succinogenes

Wolinella succinogenes grown with nitrate as terminal electron acceptor contains two nitrite reductases as measured with the donor viologen radical, one in the cytoplasm and the other integrated in the cytoplasmic membrane. The fumarate-grown bacteria contain only the membraneous species.The isolated membraneous enzyme consists of a single polypeptide chain (M _r 63,000) carrying 4 hemeC groups and probably an iron-sulphur cluster as prosthetic groups. The enzyme amounts to about 1% of the total membrane protein.The isolated enzyme catalyses the reduction of nitrite to ammonium without accumulation of significant amounts of intermediates or alternative products. The Michaelis constant for nitrite was 0.1 mM and the turnover number of the hemeC 1.5 · 10⁵ electrons per min at 37°C.The viologen-reactive site of the enzyme in the membrane is oriented towards the cytoplasm. When the isolated enzyme is incorporated into liposomes, the viologen-as well as the nitrite-reactive site is exposed to thooutside.The cytoplasmic membrane contains a second hemeC protein (M _r 22,000) which may represent a cytochrome c.Abbreviations NQNO 2-(n-nonyl)-4-hydroxyquinoline-N-oxide - MES 2-(N-morpholino)ethanesulfonate - MOPS 3-(N-morpholino)propanesulfonate - HEPES N-2-Hydroxyethylpiperazine-N-2-ethanesulfonate - TES N-tris(hydroxymethyl)methyl-2-aminoethanesulfonate - MK menaquinone     

A periplasmic flavoprotein in Wolinella succinogenes that resembles the fumarate reductase of Shewanella putrefaciens

During growth with fumarate as the terminal electron transport acceptor and either formate or sulfide as the electron donor, Wolinella succinogenes induced a peri-plasmic protein (54 kDa) that reacted with an antiserum raised against the periplasmic fumarate reductase (Fcc) of Shewanella putrefaciens. However, the periplasmic cell fraction of W. succinogenes did not catalyze fumarate reduction with viologen radicals. W. succinogenes grown with polysulfide instead of fumarate contained much less (< 10%) of the 54-kDa antigen, and the antigen was not detectable in nitrate-grown bacteria. The antigen was most likely encoded by the fccA gene of W. succinogenes. The antigen was absent from a ΔfccABC mutant, and its size is close to that of the protein predicted by fccA. The fccA gene probably encodes a pre-protein carrying an N-terminal signal peptide. The sequence of the mature FccA (481 residues, 52.4 kDa) is similar (31% identity) to that of the C-terminal part (450 residues) of S. putrefaciens fumarate reductase. As indicated by Northern blot analysis, fccA is cotranscribed with fccB and fccC. The proteins predicted from the fccB and fccC gene sequences represent tetraheme cytochromes c. FccB is similar to the N-terminal part (150 residues) of S. putrefaciens fumarate reductase, while FccC resembles the tetraheme cytochromes c of the NirT/NapC family. The ΔfccABC mutant of W. succinogenes grew with fumarate and formate or sulfide, suggesting that the deleted proteins were not required for fumarate respiration with either electron donor. Received: 26 September 1997 / Accepted: 8 December     

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