Growth ofClostridium thermoaceticum on H2/CO2 or CO as energy source

The type strain Fontaine ofClostridium thermoaceticum proliferated on H₂/CO₂ as energy source and was culturally adapted to grow on 100% CO in the headspace. The doubling times at 55°C on CO or H₂/CO₂ were 16 and 18 h, respectively. Under these conditions, the substrate-product transformation stoichiometries observed were: 4H₂+2.1CO₂→0.9 acetate and 4CO→2CO₂+1.1 acetate. It is concluded thatC. thermoaceticum has a single carbon growth physiology.     

Metabolic regulation in Pseudomonas oxalaticus OX1

Diauxic growth of Pseudomonas oxalaticus was observed on a mixture of formate and oxalate in batch cultures. In the first phase of growth only formate was used. The capacity to oxidize oxalate appeared during the lag phase of 2–4 h after the exhaustion of formate and was followed by a second phase of growth on oxalate. The rate of autotrophic ¹⁴CO₂ fixation measured in washed cell suspensions decreased markedly in this second growth phase on the addition of oxalate. In mixtures of formate with acetate, glyoxylate or glycollate, simultaneous utilization of both substrates was observed. During growth on acetate plus formate formate-oxidizing capacity remained low. With low acetate concentrations, sufficient formate remained after the exhaustion of acetate to support a second growth phase on formate. This phase followed a 1.5–2 h lag, during which formate-oxidizing capacity increased and the Calvin cycle enzymes were synthesized. In mixtures of formate with glyoxylate or glycollate, the formate-oxidizing capacity was high, formate was oxidized rapidly, and no second growth phase was seen. In these latter mixtures high activities of a membrane-bound, phenazine methosulphate/2,6-dichlorophenolindophenollinked formate dehydrogenase and low activities of the soluble NAD-linked formate dehydrogenase were detected. The synthesis of ribulose-1,5-diphosphate carboxylase was totally repressed during growth on formate plus glycollate and partially repressed on formate plus glyoxylate. The regulation of Calvin cyclus enzymes in Pseudomonas oxalaticus is discussed.     

Influence of nitrate on oxalate- and glyoxylate-dependent growth and acetogenesis by Moorella thermoacetica

Oxalate and glyoxylate supported growth and acetate synthesis by Moorella thermoacetica in the presence of nitrate under basal (without yeast extract) culture conditions. In oxalate cultures, acetate formation occurred concomitant with growth and nitrate was reduced in the stationary phase. Growth in the presence of [(14)C]bicarbonate or [(14)C]oxalate showed that CO(2) reduction to acetate and biomass or oxalate oxidation to CO(2) was not affected by nitrate. However, cells engaged in oxalate-dependent acetogenesis in the presence of nitrate lacked a membranous b-type cytochrome, which was present in cells grown in the absence of nitrate. In glyoxylate cultures, growth was coupled to nitrate reduction and acetate was formed in the stationary phase after nitrate was totally consumed. In the absence of nitrate, glyoxylate-grown cells incorporated less CO(2) into biomass than oxalate-grown cells. CO(2) conversion to biomass by glyoxylate-grown cells decreased when cells were grown in the presence of nitrate. These results suggest that: (1) oxalate-grown cells prefer CO(2) as an electron sink and bypass the nitrate block on the acetyl-CoA pathway at the level of reductant flow and (2) glyoxylate-grown cells prefer nitrate as an electron sink and bypass the nitrate block of the acetyl-CoA pathway by assimilating carbon via an unknown process that supplements or replaces the acetyl-CoA pathway. In this regard, enzymes of known pathways for the assimilation of two-carbon compounds were not detected in glyoxylate- or oxalate-grown cells.     

Nitrite as an Energy-Conserving Electron Sink for the Acetogenic Bacterium <Emphasis Type="Italic">Moorella thermoacetica</Emphasis>

Nitrite served as an energy-conserving electron acceptor for the acetogenic bacterium Moorella thermoacetica. Growth occurred in an undefined (0.1% yeast extract) medium containing 20 mM glyoxylate and 5 mM nitrite and was essentially equivalent to that observed in the absence of nitrite. In the presence of nitrite, acetate (the normal product of glyoxylate-derived acetogenesis) was not detected during growth. Instead, growth was coupled to nitrite dissimilation to ammonium, and acetogenesis was limited to the stationary phase. Furthermore, membranes from glyoxylate-grown cells under nitrite-dissimilating conditions were deficient in the b-type cytochrome that is typically found in the membranes of acetogenic cells. Unlike glyoxylate, other acetogenic substrates (fructose, oxalate, glycolate, vanillin, and hydrogen) were not growth supportive in the undefined medium containing nitrite, and glyoxylate-dependent growth did not occur in a nitrite-supplemented, basal (without yeast extract) medium. Glyoxylate-dependent growth by Moorella thermoautotrophica was not observed in the undefined medium containing nitrite. Received: 1 April 2002 / Accepted: 9 July 2002     

The inhibition of oxalate biosynthesis in isolated perfused rat liver by DL-phenyllactate and n-heptanoate

Glycolate oxidase was isolated and partially purified from human and rat liver. The enzyme preparation readily catalyzed the oxidation of glycolate, glyoxylate, lactate, hydroxyisocaproate and α-hydroxybutyrate. The oxidation of glycolate and glyoxylate by glycolate oxidase was completely inhibited by 0.02 m dl-phenyllactate or n-heptanoate. The oxidation of glyoxylate by lactic dehydrogenase or xanthine oxidase was not inhibited by 0.067 m dl-phenyllactate or n-heptanoate. The conversion of [U-¹⁴C] glyoxylate to [¹⁴C] oxalate by isolated perfused rat liver was completely inhibited by dl-phenyllactate and n-heptanoate confirming the major contribution of glycolate oxidase in oxalate synthesis. Since the inhibition of oxalate was 100%, lactic dehydrogenase and xanthine oxidase do not contribute to oxalate biosynthesis in isolated perfused rat liver. dl-Phenyllactate also inhibited [¹⁴C] oxalate synthesis from [1-¹⁴C] glycolate, [U-¹⁴C] ethylene glycol, [U-¹⁴C] glycine, [3-¹⁴C] serine, and [U-¹⁴C] ethanolamine in isolated perfused rat liver. Oxalate synthesis from ethylene glycol was inhibited by dl-phenyllactate in the intact male rat confirming the role of glycolate oxidase in oxalate synthesis in vivo and indicating the feasibility of regulating oxalate metabolism in primary hyperoxaluria, ethylene glycol poisoning, and kidney stone formation by enzyme inhibitors.     

The role of tungstate and/or molybdate in the formation of aldehyde oxidoreductase in Clostridium thermoaceticum and other acetogens; immunological distances of such enzymes

Besides Clostridium thermoaceticum and C. formicoaceticum other resting acetogenic clostridia such as C. aceticum and C. thermoautotrophicum and to a lesser extent non-clostridial acetogens such as Butyribacterium methylotrophicum and Eubacterium limosum were able to reduce propionate to propanol at the expense of carbon monoxide or formate. Methylviologen usually increased the reduction rate. Ten M molybdate in the growth medium decreased this capability for C. thermoaceticum but increased it or had no effect for the other organisms. Ten M tungstate in the growth medium increased the aldehyde oxidoreductase activity in all organisms. Crude extracts of C. thermoaceticum cells grown in the presence of 10 M or 1 mM molybdate showed by ELISA the same or even a 4 fold concentration of aldehyde oxidoreductase in the latter case. However, the enzymic activity was very low in both cases. Omission of dithionite in the growth medium diminished the antigen by a factor of about 8. The immunological distance between the enzyme from C. thermoaceticum and C. thermoautotrophicum was rather low but very large to C. formicoaceticum and undeterminably large to the other organisms.Abbreviations Ald-DH aldehyde dehydrogenase - AOR aldehyde oxidoreductase - CO-DH carbon-monoxide dehydrogenase - ELI-SA enzyme-linked immunosorbent assay - FDH formate dehydrogenase - MV methylviologen - V⁺⁺ oxidised - V^+. reduced viologen     

Effect of tolbutamide on the metabolism of Tetrahymena

Tolbutamide partially inhibited the growth but increased the glycogen content of Tetrahymena pyriformis in logarithmically growing cultures. Tolbutamide slightly increased ¹⁴CO² production from [1-¹⁴C] and [6-¹⁴HC] glucose and [2-¹⁴C] pyruvate, but had little effect on the oxidation of [1-¹⁴C] acetate when any of these substrates were added to the proteose-peptone medium in which the cells had been grown. Measurement of ¹⁴CO₂ production from [1-¹⁴C] and [2-^I4C]-glyoxylate showed that this substrate was primarily oxidized via the glyoxylate cycle, with little if any oxidation occurring via the peroxisomal glyoxylate oxidase. Addition of tolbutamide inhibited the glyoxylate cycle as indicated by a marked reduction in label appearing in CO₂ and in glycogen from labeled acetate. In control cells, addition of acetate strongly inhibited the oxidation of [2-¹⁴C]-pyruvate whereas addition of pyruvate had little effect on the oxidation of [1-¹⁴C]-acetate. Acetate was more effective than pyruvate in preventing the growth inhibitory and glycogen-increasing effects of tolbutamide. The data suggest that one effect of tolbutamide may be to interfere with the transfer of isocitrate and acetyl CoA across mitochondrial membranes.     

Substrate Utilization by an Oxalate-Consuming Spirillum Species in Relation to Its Growth in Ozonated Water

The nutritional versatility of a vibrio-shaped, oxalate-utilizing isolate, strain NOX, obtained from tap water supplied with low concentrations of formate, glyoxylate, and oxalate, was determined by growth experiments with low-molecular-weight carbon compounds at high (grams per liter) and very low (micrograms per liter) concentrations. The organism, which was identified as a Spirillum species, appeared to be specialized in the utilization of a number of carboxylic acids. Yields of 2.9 × 10⁶ CFU/μg of oxalate C and 1.2 × 10⁷ CFU/μg of acetate C were obtained from growth experiments in tap water supplied with various low amounts of either oxalate or acetate. A substrate saturation constant of 0.64 μM oxalate was calculated for strain NOX from the relationship between growth rate and concentration of added oxalate. Maximum colony counts of strain NOX grown in ozonated water (dosages of 2.0 to 3.2 mg of O₃ per liter) were 15 to 20 times larger than the maximum colony counts of strain NOX grown in water before ozonation. Based on the nutritional requirements of strain NOX, it was concluded that carboxylic acids were produced by ozonation. Oxalate concentrations were calculated from the maximum colony counts of strain NOX grown in samples of ozonated water in which a non-oxalate-utilizing strain of Pseudomonas fluorescens had already reached maximum growth. The oxalate concentrations obtained by this procedure ranged from 130 to 220 μg of C/liter.     

Specific features of the synthesis of the exopolysaccharide ethapolan on a mixture of energy-deficient growth substrates

Intensification of the synthesis of the microbial exopolysaccharide ethapolan by Acinetobacter sp. B-7005 was shown to occur on a mixture of energy-deficient growth substrates (acetate + glucose). When the bacterium grew on the substrate mixture, both substrates were utilized simultaneously; acetate was taken up by means of active transport at the expense of the energy of the proton-motive force. When acetate was present in the form of a sodium salt, the activities of acetyl-CoA synthetase and phosphoenolpyruvate synthetase (the key enzyme of gluconeogenesis) were tenfold higher than in the presence of potassium acetate, and the indexes of ethapolan synthesis were two times higher. The positive effect of Na⁺ on ethapolan synthesis is supposed to consist in the creation of ion gradients on the membrane, necessary for the generation of the proton-motive force. Simultaneous functioning of the glyoxylate cycle and pyruvate carboxylase reaction, as well as an increase in the activity of isocitrate lyase, malate synthease, and phosphoenolpyruvate synthetase, provide evidence of increased gluconeogenesis in the presence of the acetate + glucose mixture (as compared to gluconeogenesis on the corresponding monosubstrates).     

Oxalate accumulation from citrate by Aspergillus niger

Carbon-14 was incorporated from citrate-1,5-¹⁴C, glyoxylate-¹⁴C(U), or glyoxylate-1-¹⁴C into oxalate by cultures of Aspergillus niger pregrown on a medium with glucose as the sole source of carbon. Glyoxylate-¹⁴C(U) was superior to glyoxylate-1-¹⁴C and citrate-1,5-¹⁴C as a source of incorporation. By addition of a great amount of citrate the accumulation of oxalate was accelerated and its maximum yield increased. In a cell-free extract from mycelium forming oxalate from citrate the enzyme oxaloacetate hydrolase (EC 3.7.1.1) was identified. Its in vitro activity per flask exceeded the rate of in vivo accumulation of oxalate. Glyoxylate oxidizing enzymes (glycolate oxidase, EC 1.1.3.1; glyoxylate oxidase, EC 1.2.3.5; NAD(P)-dependent glyoxylate dehydrogenase; glyoxylate dehydrogenase, CoA-oxalylating, EC 1.2.1.17) could not be detected in cell-free extracts. It is concluded that in cultures accumulating oxalate from citrate after pregrowth on glucose, oxalate arises by hydrolytic cleavage of oxaloacetate but not by oxidation of glyoxylate.Abbreviations Used DCPIP 2,6-dichlorophenolindophenol     

Acetic Acid Production by Clostridium thermoaceticum in pH-Controlled Batch Fermentations at Acidic pH

Four strains of the homofermentative, obligately anaerobic thermophile Clostridium thermoaceticum were compared in pH-controlled batch fermentation for their tolerance to acetic acid, efficiency of converting glucose to acetic acid and cell mass, and growth rate. At pH 6 (and pH 7) and initial acetic acid concentrations of less than 10 g/liter, the four strains had mass doubling times of 5 to 7 h and conversion efficiencies to acetic acid and cell mass of about 90% (70 to 110%) and 10%, respectively. At pH 6 and initial acetic acid concentrations of greater than 10 g/liter, only two of the strains grew, the mass doubling time increased to 18 h, and the conversion efficiencies to acetic acid and cell mass remained unchanged. Both of these strains had been selected for their ability to grow in the presence of acetate at neutral pH. The highest acetic acid concentrations reached were about 15 and 20 g/liter at pH 6 and 7, respectively. C. thermoaceticum is apparently more sensitive to free acetic acid than to either acetate ion or pH. It was also shown that, at pH 6 and 7, the redox potential must be at least as low as −300 and −360 mV, respectively, for growth to occur.     

Oxalate metabolism by tobacco leaf discs

The turnover rate of oxalate in leaf discs of Nicotiana tabacum, var Havana Seed, during photosynthesis was estimated to be 1 to 2 micromoles per gram fresh weight per hour. Radioactivity from the enzymic oxidation of [¹⁴C]oxalate rapidly appeared in neutral sugars (mainly sucrose), organic acids (mainly malate), and amino acids. Only 5% of the radioactivity was released to the atmosphere as ¹⁴CO₂, and no formate or formaldehyde could be detected. The metabolism of oxalate was not increased by raising the O₂ concentration from 1% to 21% to 60%, nor was the formation of [¹⁴C]oxalate from [2-¹⁴C]glyoxylate changed under the same conditions as was previously observed in vitro (Havir 1983 Plant Physiol 71: 874-878). While oxalate is not an inert end product of the glycolate pathway, it contributes little to the formation of photorespiratory CO₂.     

Oxalate synthesis from [14C1]glycollate and [14C1]glycoxylate in the hepatectomized rat

Hepatectomy significantly altered the metabolism of [1-¹⁴C]glyoxylate and [1-¹⁴C]glycollate in the rat. The production of ¹⁴CO₂ was reduced by 47% and 77%–86%, respectively, indicating the involvement of the liver in the oxidation of both substrates. Unidentified intermediates, assumed to be primary glycine, serine and ethanolamine, were also reduced by over 50%, was would be expected from the removal of the aminotransferase enzymes through the hepatectomy. The biosynthesis of [¹⁴C]oxalate from [1-¹⁴C]glycollate was reduced by more than 80% in the hepatectomized rat. This suggests that this oxidation is primarily catalyzed by the liver enzymes, glycolic acid oxidase and glycolic acid dehydrogenase, in the intact rat. The limited formation of [¹⁴C]oxalate from [¹⁴₁]glycollate observed in the hepatectomized rat is probably catalyzed by lactate dehydrogenase or extrahepatic glycolic acid oxidase. Hepatectomy did not significantly alter the rate of formation of [¹⁴C]oxalate from [¹⁴₁]glyoxylate. However, since saturating concentrations of glyoxylate could not be used because of the toxicity of this substrate, the involvement of glycollic acid oxidase in this oxidation reaction in the intact rat can not be ruled out. In the hepatectomized rat, lactate dehydrogenase appears to be the enzyme making the major contribution, although other as yet not identified enzymes may be contributing. The increased deposition of oxalate in the tissues, oxalosis, may result from the shift in oxalate synthesis from the liver to the extrahepatic tissues.     

Manganese Peroxidase-Dependent Oxidation of Glyoxylic and Oxalic Acids Synthesized by Ceriporiopsis subvermispora Produces Extracellular Hydrogen Peroxide

The ligninolytic system of the basidiomycete Ceriporiopsis subvermispora is composed of manganese peroxidase (MnP) and laccase. In this work, the source of extracellular hydrogen peroxide required for MnP activity was investigated. Our attention was focused on the possibility that hydrogen peroxide might be generated by MnP itself through the oxidation of organic acids secreted by the fungus. Both oxalate and glyoxylate were found in the extracellular fluid of C. subvermispora cultures grown in chemically defined media, where MnP is also secreted. The in vivo oxidation of oxalate was measured; ¹⁴CO₂ evolution was monitored after addition of exogenous [¹⁴C]oxalate to cultures at constant specific activity. In standard cultures, evolution of CO₂ from oxalate was maximal at day 6, although the MnP titers were highest at day 12, the oxalate concentration was maximal (2.5 mM) at day 10, and the glyoxylate concentration was maximal (0.24 mM) at day 5. However, in cultures containing low nitrogen levels, in which the pH is more stable, a better correlation between MnP titers and mineralization of oxalate was observed. Both MnP activity and oxidation of [¹⁴C]oxalate were negligible in cultures lacking Mn(II). In vitro assays confirmed that Mn(II)-dependent oxidation of [¹⁴C]oxalate by MnP occurs and that this reaction is stimulated by glyoxylate at the concentrations found in cultures. In addition, both organic acids supported phenol red oxidation by MnP without added hydrogen peroxide, and glyoxylate was more reactive than oxalate in this reaction. Based on these results, a model is proposed for the extracellular production of hydrogen peroxide by C. subvermispora.     

Nitrite as an energy-conserving electron sink for the acetogenic bacterium Moorella thermoacetica

Nitrite served as an energy-conserving electron acceptor for the acetogenic bacterium Moorella thermoacetica. Growth occurred in an undefined (0.1% yeast extract) medium containing 20 m M glyoxylate and 5 m M nitrite and was essentially equivalent to that observed in the absence of nitrite. In the presence of nitrite, acetate (the normal product of glyoxylate-derived acetogenesis) was not detected during growth. Instead, growth was coupled to nitrite dissimilation to ammonium, and acetogenesis was limited to the stationary phase. Furthermore, membranes from glyoxylate-grown cells under nitrite-dissimilating conditions were deficient in the b-type cytochrome that is typically found in the membranes of acetogenic cells. Unlike glyoxylate, other acetogenic substrates (fructose, oxalate, glycolate, vanillin, and hydrogen) were not growth supportive in the undefined medium containing nitrite, and glyoxylate-dependent growth did not occur in a nitrite-supplemented, basal (without yeast extract) medium. Glyoxylate-dependent growth by Moorella thermoautotrophica was not observed in the undefined medium containing nitrite.     

Metabolism of Glycolate in Isolated Spinach Leaf Peroxisomes : KINETICS OF GLYOXYLATE, OXALATE, CARBON DIOXIDE, AND GLYCINE FORMATION

The flow of glyoxylate derived from glycolate into various metabolic routes in the peroxisomes during photorespiration was assessed. Isolated spinach leaf peroxisomes were fed [¹⁴C] glycolate in the absence or presence of exogenous glutamate, and the formation of radioactive glyoxylate, CO₂, glycine, oxalate, and formate was monitored at time intervals. In the absence of glutamate, 80% of the glycolate was consumed within 2 hours and concomitantly glyoxylate accumulated; CO₂, oxalate, and formate each accounted for less than 5% of the consumed glycolate. In the presence of equal concentration of glutamate, glycolate was metabolized at a similar rate, and glycine together with some glyoxylate accumulated; CO₂, oxalate, and formate each accounted for an even lesser percentage of the consumed glycolate. CO₂ and oxalate were not produced in significant amounts even in the absence of glutamate, unless glycolate had been consumed completely and glyoxylate had accumulated for a prolonged period. These in vitro findings are discussed in relation to the extent of CO₂ and oxalate generated in leaf peroxisomes during photorespiration.     

Purification and properties of acetate kinase from Clostridium thermoaceticum

Acetate kinase (ATP: acetate phosphotransferase EC 2.7.2.1) has been purified from Clostridium thermoaceticum. The enzyme of a specific activity of 282 μmoles min^-1 mg^-1 appeared homogeneous as judged from Sephadex chromatography and sedimentation velocity. Polyacrylamide gel electrophoretic patterns at pH 9.0 and 9.5 showed heterogeneity. Velocity curves obtained with varying amount of acetate were of the Michaelis-Menten type with an apparent K _m of 0.135 M. With varying amounts of ATP sigmoidal kinetic was observed (S_0.5=1.64 mM), suggesting cooperative binding of this substrate. The enzyme had only moderate thermal stability with a temperature optimum of about 60°C and exhibited a broken line in an Arrhenius graph. From gel filtration a molecular weight of about 60 000 daltons was estimated for the enzyme. The S_20w value was 6.0 S.     

Microbial growth on oxalate by a route not involving glyoxylate carboligase

1. The metabolism of oxalate by the pink-pigmented organisms, Pseudomonas AM1, Pseudomonas AM2, Protaminobacter ruber and Pseudomonas extorquens has been compared with that of the non-pigmented Pseudomonas oxalaticus. 2. During growth on oxalate, all the organisms contain oxalyl-CoA decarboxylase, formate dehydrogenase and oxalyl-CoA reductase. This is consistent with oxidation of oxalate to carbon dioxide taking place via oxalyl-CoA, formyl-CoA and formate as intermediates, and also reduction of oxalate to glyoxylate taking place via oxalyl-CoA. 3. The pink-pigmented organisms, when grown on oxalate, contain l-serine–glyoxylate aminotransferase and hydroxypyruvate reductase but do not contain glyoxylate carboligase. The converse of this obtains in oxalate-grown Ps. oxalaticus. This indicates that, in contrast with Ps. oxalaticus, synthesis of C₃ compounds from oxalate by the pink-pigmented organisms occurs by a variant of the `serine pathway' used by Pseudomonas AM1 during growth on C₁ compounds. 4. Evidence in favour of this scheme is provided by the finding that a mutant of Pseudomonas AM1 that lacks hydroxypyruvate reductase is not able to grow on oxalate.     

Ruminococcus hydrogenotrophicus sp. nov., a new H2/CO2-utilizing acetogenic bacterium isolated from human feces

A new H₂/CO₂-utilizing acetogenic bacterium was isolated from the feces of a non-methane-excreting human subject. The two strains S5a33 and S5a36 were strictly anaerobic, gram-positive, non-sporulating coccobacilli. The isolates grew autotrophically by metabolizing H₂/CO₂ to form acetate as sole metabolite and were also able to grow heterotrophically on a variety of organic compounds. The major end product of glucose and fructose fermentation was acetate; the strains also formed ethanol, lactate and, to a lesser extent, isobutyrate and isovalerate. The G+C content of DNA of strain S5a33 was 45.2 mol%. 16S rRNA gene sequencing demonstrated that the two acetogenic isolates were phylogenetically identical and represent a new subline within Clostridium cluster XIVa. Based on phenotypic and phylogenetic considerations, a new species, Ruminococcus hydrogenotrophicus, is proposed. The type strain of R. hydrogenotrophicus is S5a33 (DSM 10507). Furthermore, H₂/CO₂ acetogenesis appeared to be a common property of most of the species phylogenetically closely related to strain S5a33 (Clostridium coccoides, Ruminococcus hansenii, and Ruminococcus productus). Received: 11 April 1996 / Accepted: 11 June 1996     

Effect of Yeast Extract on Growth and Metabolism of H2-Utilizing Acetogenic Bacteria from the Human Colon

The aim of this work was to determine the effect of yeast extract and of its vitamin contents on autotrophic and heterotrophic growth and metabolism of four acetogenic bacteria from the human colon. Yeast extract exerted a stimulatory effect on autotrophic growth of the colonic acetogens, but concentration of this compound above 1–2 g. L⁻¹ in the medium did not enhance utilization of H₂/CO₂. Vitamins provided by yeast extract were shown to be essential cofactors of the reductive pathway of acetate synthesis except for one Clostridium strain. Yeast extract was also necessary to maintain heterotrophic growth and acetate synthesis from glucose in acetogenic species, except in the Streptococcus strain. In the absence of yeast extract, vitamins could efficiently restore glucose fermentation via acetate. The reductive and oxidative pathways of acetate synthesis might, therefore, depend on vitamin cofactors supplied by yeast extract in most of the human acetogenic bacteria. Non-vitaminic factors appeared also to be involved in the metabolism of some of these acetogenic species. Received: 6 March 1998 / Accepted: 3 April 1998