Isolation and physiological characterization of Syntrophus buswellii strain GA from a syntrophic benzoate-degrading,strictly anaerobic coculture

A stable, syntrophic benzoate-degrading bacterial consortium was enriched from sewage sludge. It oxidized benzoate or 3-phenylpropionate to acetate, H₂ and CO₂. As hydrogen scavengers Methanospirillum hungatei and Desulfovibrio sp. were present. The benzoate-degrading bacteria of this syntrophic culture and of Syntrophus buswelli were able to grow with benzoate/crotonate or crotonate alone in the absence of a hydrogen-utilizing partner organism. If crotonate was the only substrate, acetate and butyrate were produced, while during growth on benzoate or 3-phenylpropionate crotonate served as a reducible co-substrate and was exclusively converted to butyrate. In the presence of crotonate interspecies hydrogen transfer was not necessary as a hydrogen sink. The benzoate degrader was isolated as a pure culture with crotonate as the only carbon source. The pure culture could also grow with benzoate/crotonate or 3-phenylpropionate/crotonate. The effect of high concentrations of crotonate and of acetate or butyrate on growth of the benzoate degrader was investigated. The benzoate degrader was compared with S. buswellii for its morphology, physiology and DNA base composition. Except for the fact that S. buswellii was also able to grow on cinnamate, no differences between the two organisms were detected. The isolate is named S. buswelli, strain GA.     

Evidence of reversed electron transport in syntrophic butyrate or benzoate oxidation by Syntrophomonas wolfei and Syntrophus buswellii

Syntrophomonas wolfei and Syntrophus buswellii were grown with butyrate or benzoate in a defined binary coculture with Methanospirillum hungatei. Both strains also grew independent of the partner bacteria with crotonate as substrate. Localization of enzymes involved in butyrate oxidation by S. wolfei revealed that ATP synthase, hydrogenase, and butyryl-CoA dehydrogenase were at least partially membrane-associated whereas 3-hydroxybutyryl-CoA dehydrogenase and crotonase were entirely cytoplasmic. Inhibition experiments with copper chloride indicated that hydrogenase faced the outer surface of the cytoplasmic membrane. Suspensions of butyrate-or benzoate-grown cells of either strain accumulated hydrogen during oxidation of butyrate or benzoate to a low concentration that was thermodynamically in equilibrium with calculated reaction energetics. The protonophore carbonylcyanide m-chlorophenyl-hydrazone (CCCP) and the proton-translocating ATPase inhibitor N,Ndicyclohexylcarbodiimide (DCCD) both specifically inhibited hydrogen formation from butyrate or benzoate at low concentrations, whereas hydrogen formation from crotonate was not affected. A menaquinone was extracted from cells of S. wolfei and S. buswellii grown syntrophically in a binary methanogenic culture. The results indicate that a proton-potential-driven process is involved in hydrogen release from butyrate or benzoate oxidation.Abbreviations BES Bromoethanesulfonate - CCCP Carbonyl cyanide-m-chlorophenyl-hydrazone - DCCD N,Ndicyclohexylcarbodiimide - DCPIP Dichlorophenol indophenol - PMS Phenazine methosulfate     

Enzymes involved in crotonate metabolism in Syntrophomonas wolfei

Cell-free extracts of Syntrophomonas wolfei subsp. wolfei grown with crotonate in pure culture or in coculture with Methanospirillum hungatei contained crotonyl-coenzyme A (CoA): acetate CoA-transferase activity. This activity was not detected in cell-free extracts from the butyrate-grown coculture which suggests that the long lag times observed before S. wolfei grew with crotonate were initially due to the inability to activate crotonate. Cell-free extracts of S. wolfei grown in pure culture contained high specific activities of hydrogenase and very low levels of formate dehydrogenase. The low levels suggest a biosynthethic rather than a catabolic role for the latter enzyme when S. wolfei is grown in pure culture. CO dehydrogenase activity was not detected. S. wolfei can form butyrate using a CoA transferase activity, but not by a phosphotransbutyrylase or enoate reductase activity. A c-type cytochrome was detected in S. wolfei grown in pure culture or in coculture indicating the presence of an electron transport system. This is a characteristic which separates S. wolfei from other known crotonate-using bacteria.     

Characterization of crotonate grown Clostridium kluyveri by its assimilatory metabolism

Summary Considerable behavioral differences were observed during growth of Clostridium kluyveri on ethanol-acetate and on crotonate media. The identity of the crotonate grown Clostridium with the ethanol grown Clostridium kluyveri was therefore established by three characteristic biosynthetic routes: 1. ribose is synthesized from CO₂ and acetate via pyruvate, triose phosphate and a non-oxidative pentose phosphate pathway, 2. reduced one-carbon units are formed predominantly from CO₂ and not from serine as usual, and 3. glutamate biogenesis follows an atypical stereochemical course.This paper contains parts of the doctoral thesis of J. W., Medizinische Fakultät, Universität Freiburg, 1968.     

Growth of Syntrophomonas wolfei in pure culture on crotonate

A Synthrophomonas wolfei-Methanospirillum hungatei coculture was adapted to catabolize crotonate. S. wolfei was then isolated in axenic culture using agar spread plates and roll tubes with crotonate as the sole energy source. S. wolfei catabolized crotonate via a disproportionation mechanism similar to that of some Clostridium species. Growth on crotonate was very slow (specific growth rate of 0.029 h^–1) but the conversion of energy into cell material was very efficient with cell yields of 14.6 g (dry wt.) per mol of crotonate. S. wolfei alone did not catabolize butyrate, but butyrate was stoichiometrically degraded to acetate and presumably methane when S. wolfei was reassociated with M. hungatei. S. wolfei-M. hungatei cocultures accumulated some butyrate during growth on crotonate indicating that protons were not the sole electron acceptors used for crotonate oxidation by the coculture.     

Ilyobacter delafieldii sp. nov., a metabolically restricted anaerobic bacterium fermenting PHB

Enrichments from an estuarine sediment with crotonate as substrate resulted in the isolation of a motile, gram-negative, obligately anaerobic rod with pointed ends, designated strain 10cr1. The organism was asporogenous, did not reduce sulfur, sulfate, thiosulfate, nitrate, oxygen or fumarate, and had a mol %G+C ratio of 29. Strain 10cr1 was able to ferment crotonate, 3-hydroxybutyrate, lactate, pyruvate, and poly--hydroxybutyric acid (PHB). Acetate, propionate, butyrate, CO₂ and H₂ were the fermentation products. When grown on PHB there was accumulation of 3-hydroxybutyrate once growth had ceased, indicating degradation of PHB to the monomer. The 3-hydroxybutyrate formed during growth of the culture was fermented to acetate, butyrate and H₂. Experimental evidence suggested the production of an extracellular PHB depolymerase. The cells were not attached to the PHB granules. This is the first isolation of an anaerobic bacterium capable of degrading exogenous PHB. This strain is described as a new species, Ilyobacter delafieldii sp. nov., and strain 10cr1 (=DSM 5704) is designated as the type (and at present, only) strain.Abbreviations G+C guanine plus cytosine - OD optical density - PHB poly--hydroxybutyric acid - specific growth rate - HPLC high-performance liquid chromatography - YE yeast extract     

Pathway of anaerobic poly-β-hydroxybutyrate degradation byIlyobacter delafieldii

Ilyobacter delafieldii produced an extracellular poly--hydroxybutyrate (PHB) depolymerase when grown on PHB; activity was not detected in cultures grown on 3-hydroxybutyrate, crotonate, pyruvate or lactate. PHB depolymerase activity was largely associated with the PHB granules (supplied as growth substrate), and only 16% was detected free in the culture supernatant. Monomeric 3-hydroxybutyrate was detectable as a product of depolymerase activity. The monomer was fermented to acetate, butyrate and H₂. After activation by coenzyme A transfer from acetyl-CoA or butyryl-CoA, the resultant 3-hydroxybutyryl-CoA was oxidized to acetoacetyl-CoA (producing NADH), followed by thiolytic cleavage to yield acetyl-CoA which was further metabolized to acetyl-phosphate, then to acetate with concomitant ATP production. The reducing equivalents (NADH) could be disposed of by the evolution of H₂, or by a reductive pathway in which 3-hydroxybutyryl-CoA was dehydrated to crotonyl-CoA and reduced to butyryl-CoA. In cocultures ofI. delafieldii withDesulfovibrio vulgaris on PHB, the H₂ partial pressure was much lower than in the pure cultures, and sulfide was produced. Thus interspecies hydrogen transfer caused a shift to increased acetate and H₂ production at the expense of butyrate.     

Fermentation of cinnamate by a mesophilic strict anaerobe,Acetivibrio multivorans sp. nov.

A cinnamate-fermenting bacterium (strain PeC1) was isolated in pure culture from anoxic sludge of an oil refinery wastewater treatment facility. It was a mesophilic gram-negative non-sporing actively motile rod. It did not reduce nitrate, sulfte, or other sulfur compounds as electron acceptors. It fermented cinnamate to 3-phenylpropionate, benzoate, and acetate; crotonate to butyrate and acetate; pyruvate to lactate and acetate; acetoin to ethanol and acetate; and carbohydrates to ethanol, formate, and acetate. The DNA base ratio of the strain was 44 mol% guanine plus cytosine. It is described as a new species of the genus Acetivibrio, A. multivorans sp. nov.     

Use of benzoate as an electron acceptor by Syntrophus aciditrophicus grown in pure culture with crotonate

In methanogenic environments, the main fate of benzoate is its oxidization to acetate, H(2) and CO(2) by syntrophic associations of hydrogen-producing benzoate degraders and hydrogen-using methanogens. Here, we report the use of benzoate as an electron acceptor. Pure cultures of S. aciditrophicus simultaneously degraded crotonate and benzoate when both substrates were present. The growth rate was 0.007 h(-1) with crotonate and benzoate present compared with 0.025 h(-1) with crotonate alone. After 8 days of incubation, 4.12 +/- 0.50 mM of cyclohexane carboxylate and 8.40 +/- 0.61 mM of acetate were formed and 4.0 +/- 0.04 mM of benzoate and 4.8 +/- 0.5 mM of crotonate were consumed. The molar growth yield was 22.7 +/- 2.1 g (dry wt) of cells per mol of crotonate compared with about 14.0 +/- 0.1 g (dry wt) of cells per mol of crotonate when S. aciditrophicus was grown with crotonate alone. Cultures grown with [ring-(13)C]-benzoate and unlabelled crotonate initially formed [ring-(13)C]-labelled cyclohexane carboxylate. No (13)C-labelled acetate was detected. In addition to cyclohexane carboxylate, (13)C-labelled cyclohex-1-ene carboxylate was detected as an intermediate. Once almost all of the benzoate was gone, carbon isotopic analyses showed that cyclohexane carboxylate was formed from both labelled and non-labelled metabolites. Glutarate and pimelate were also detected at this time and carbon isotopic analyses showed that each was made from a mixture labelled and non-labelled metabolites. The increase in molar growth yield with crotonate and benzoate and the formation of [ring-(13)C]-cyclohexane carboxylate from [ring-(13)C]-benzoate in the presence of crotonate are consistent with benzoate serving as an electron acceptor.     

Utilization of (E)-2-butenoate (Crotonate) by Clostridium kluyveri and some other Clostridium species

Clostridium La 1 obtained from a Clostridium kluyveri culture was compared with a typical C. kluyvery strain (DSM 555). The former grows on crotonate and is unable to use ethanol-acetate as carbon sources. The latter grows on crotonate only after long adaptation periods. Resting cells of both strains show also pronounced differences in the fermentation of crotonate. This holds even for C. kluyveri grown on crotonate. Besides several other differences the most striking is that there is no hybridization between the DNA of both strains.Crotonate seems not to be a very special carbon source since C. butyricum and C. pasteurianum grow on crotonate medium supplemented by peptone and yeast extract.Non Standard Abbreviations EA-medium ethanol and acetate as carbon source - C-medium crotonate as carbon source - DSM Deutsche Sammlung von Mikroorganismen     

Acetate metabolism inMethanosarcina barkeri

Methanosarcina barkeri was grown by acetate fermentation in complex medium (N₂ gas phase). The molar growth yield was 1.6–1.9 g cells/mol methane formed. Under these conditions 63–82% of the methane produced byMethanosarcina strains was derived from the methyl carbon of acetate, indicating that some methane was derived from other media components. Growth was not demonstrated in complex media lacking acetate or mineral acetate medium containing acetate but lacking H₂/CO₂, methanol, or trypticase and yeast extract. Acetate metabolism byM. barkeri strain MS was further exmined in mineral acetate medium containing H₂/CO₂ and/or methanol, but lacking cysteine. Under these conditions, more methane was derived from the methyl carbon of acetate than from the carboxyl carbon. Methanogenesis from the methyl group increased with increasing acetate concentration. The methyl carbon contributed up to 42% of the methane formed with H₂/CO₂ and up to 5% with methanol. Methanol stimulated the oxidation of the methyl group of acetate to CO₂. The average rates of methane formation from acetate were 1.3 nomol/min ·ml/culture (0.04mg² cell dry weight) in defined media (gas phase H₂/CO₂) and complex media (gas phase N₂). Acetate contributed up to 60% of cell carbon formed under the growth conditions examined. Similar quantities of cell carbon were derived from the methyl and carboxyl carbons of acetate, suggesting incorporation of this compound as a two-carbon unit. Incorporated acetate was not preferentially localized in lipid material, as 70% of the incorporated acetate was found in the wall and protein cell fractions. Acetate catabolism was stimulated by pregrowing of cultures in media containing acetate, while acetate anabolism was not influenced. The results are discussed in terms of the differences between the mechanisms of acetate catabolism and anabolism.Abbreviations CH₃-S-CoM methyl coenzyme M - TCA trichloroacetic acid - CoM coenzyme M (2-mercaptoethane sulfonic acid) - E^o standard potential change (pH 7) - F₄₂₀ Factor 420, a low redox electron carrier - G^o standard free energy change (pH 7) - kJ kilojoules (=0.24 kilocalories) - PBBW Weimer's phosphate-buffered basal medium - X unknown C₁ carrier     

Catalysis of an isotopic exchange between CO2 and the carboxyl group of acetate by Methanosarcina barkeri grown on acetate

Cell suspensions of Methanosarcina barkeri (strain Fusaro) grown on acetate were found to catalyze the formation of methane and CO₂ from acetate (30–40 nmol/min·mg protein) and an isotopic exchange between the carboxyl group of acetate and ¹⁴CO₂ (30–40 nmol/min·mg protein). An isotopic exchange between [¹⁴C]-formate and acetate was not observed. Cells grown on methanol mediated neither methane formation from acetate nor the exchange reactions. The data indicate that the isotopic exchange between CO₂ and the carboxyl group of acetate is a partial reaction of methanogenesis from acetate. Both reactions were completely inhibited by low concentrations of cyanide (20 M) or of hydrogen (0.5% in the gas phase). Methane formation from acetate was also completely inhibited by low concentrations of carbon monoxide (0.2% in the gas phase) whereas only significantly higher concentrations of CO had an effect on the exchange reaction. In the concentration range tested KCN, H₂ and CO had no effect on methane formation from methanol or from H₂ and CO₂; however, cyanide (20 M) also affected methane formation from CO. The results are discussed with respect to proposed mechanisms of methane and CO₂ formation from acetate.     

Growth yields and energy generation by Campylobacter sputorum subspecies bubulus during growth in continuous culture with different hydrogen acceptors

Campylobacter sputorum subspecies bubulus was grown in continuous culture with excess of l-lactate or formate, and growth-limiting amounts of oxygen, fumarate, nitrate or nitrite. l-Lactate was oxidized to acetate, fumarate was reduced to succinate, and nitrate and nitrite were reduced to ammonia. The Y _lactate values (g dry weight bacteria/g mol lactate) for the respective hydrogen acceptors were much higher than the Y _formate values. Steady state cultures on formate and nitrite could only be obtained at a low dilution rate and low nitrite concentrations in the growth medium. In H⁺/2e measurements with lactate-grown cells proton ejections were observed with lactate or pyruvate as a hydrogen donor, and oxygen or hydrogen peroxide as a hydrogen acceptor. Proton ejection was also observed with pyruvate and nitrate. Proton ejection did not occur with lactate and nitrate, neither with lactate or pyruvate and fumarate or nitrite. With formate as a hydrogen donor acidification occurred with all hydrogen acceptors mentioned. It has been concluded that during growth on lactate and fumarate or nitrite substrate level phosphorylation at acetate formation is the sole ATP-generating system. Growth on formate and fumarate or nitrite is explained by a proton gradient generated as a result of oxidation of formate at the periplasmic side of the cytoplasmic membrane. With oxygen and nitrate additional ATP is formed by electron transport-linked phosphorylation. The low molar growth yields with formate are explained by the observation that formate-grown cells had a great permeability to protons.Abbreviations H⁺/2e value number of protons ejected per electron pair transported in the respiratory system - P/2e value mol of ATP formed per electron pair transported in the respiratory system - CCCP carbonyl cyanide m-chlorophenyl-hydrazone     

Reisolation of the carbon monoxide utilizing hydrogen bacterium Pseudomonas carboxydovorans (Kistner) comb. nov.

From enrichment cultures four carbon monoxide utilizing bacteria were isolated; strain OM5 isolated from waste water was studied in detail. The cells are Gram-negative, slightly curved rods, motile by a single subpolarly inserted flagellum. The colonies are smooth, translucent and not slimy.The cells are able to grow autotrophically in mineral medium under an atmosphere of 40% CO, 5% O₂ and 55% N₂ at a doubling time of 20h (30°C) or of 85% H₂, 5% O₂ and 10% CO₂ at a doubling time of 7h. Heterotrophic growth occurrd on organic acids such as acetate (t _d =8h), pyruvate (t _d =8h), lactate, crotonate, malate, succinate (t _d =8h), formate (t _d =35h) and glyoxylate as substrates.The enzyme system for carbon monoxide utilization is formed only during growth on CO; hydrogenase is present in cells grown on CO or on H₂+CO₂ as well as grown on pyruvate. The rate of oxygen reduction by intact CO-grown cells is 3.7-fold higher in the presence of hydrogen than in the presence of carbon monoxide. During growth the stoichiometry of gas uptake was 6.1 CO+2.8 O₂+H₂O CH₂O+5.1 CO₂. For the new isolate the name Pseudomonas carboxydovorans (Kistner) comb. nov. has been proposed.Part of this work was presented at the Second International Symposium on Microbial Growth on C₁-Compounds in Puschino, USSR, September 12th–16th, 1977.     

Electron-transport chain and coupled oxidative phosphorylation in methanol-grown Paracoccus denitrificans

Methanol dehydrogenase of Paracoccus denitrificans was shown to be very similar to the enzyme of Pseudomonas sp, M. 27. The K _m value for methanol with excess activator (ammonium ions) is 35 M. The pH optimum for enzyme activity with 2,6-dichlorophe-nolindophenol as electronacceptor was at 9.0 A CO-binding type of cytochrome c was present only in cells grown with methanol as carbon and energy source.It has been shown that methanol-oxidation involves electron-transport via cytochrome c and an a-type cytochrome to oxygen. Antimycin A did not inhibit this electron transport and 90% inhibition was obtained by 375 M potassium cyanide. Electron transport from endogenous substrates is possible via cytochrome b and possibly cytochrome o to oxygen. Potassium cyanide inhibited 90% of the electron transport via this pathway at a concentration of 1.42 mM. Measurement of respiration-driven proton translocation proved that during oxidation of methanol to formaldehyde by oxygen one mole of adenosine triphosphate is synthesized in the site 3 region of the electron transport chain. The H⁺/O value found confirmed the H⁺/site ratio of 3–4 found in heterotrophic grown cells. During electron transport from endogenous substrates to oxygen there is a possible synthesis of 3 moles of adenosine triphosphate.In heterotrophically grown cells electron transfer to oxygen follows almost only the branch of the respiratory chain containing cytochrome o. In methanol-grown cells the pathway via the a-type cytochrome seems more important.Abbreviations DCPIP 2,6-dichlorophenolindophenol - PMS phenazine methosulphate - EPR electron paramagnetic resonance - S.D. standard deviation - ATP adenosine triphosphate     

Cyclohexane carboxylate and benzoate formation from crotonate in Syntrophus aciditrophicus

The anaerobic, syntrophic bacterium Syntrophus aciditrophicus grown in pure culture produced 1.4 +/- 0.24 mol of acetate and 0.16 +/- 0.02 mol of cyclohexane carboxylate per mole of crotonate metabolized. [U-13C]crotonate was metabolized to [1,2-(13)C]acetate and [1,2,3,4,5,7-(13)C]cyclohexane carboxylate. Cultures grown with unlabeled crotonate and [13C]sodium bicarbonate formed [6-(13)C]cyclohexane carboxylate. Trimethylsilyl (TMS) derivatives of cyclohexane carboxylate, cyclohex-1-ene carboxylate, benzoate, pimelate, glutarate, 3-hydroxybutyrate, and acetoacetate were detected as intermediates by comparison of retention times and mass spectral profiles to authentic standards. With [U-(13)C]crotonate, the m/z-15 ion of TMS-derivatized glutarate, 3-hydroxybutyrate, and acetoacetate each increased by +4 mass units, and the m/z-15 ion of TMS-derivatized pimelate, cyclohex-1-ene carboxylate, benzoate, and cyclohexane carboxylate each increased by +6 mass units. With [13C]sodium bicarbonate and unlabeled crotonate, the m/z-15 ion of TMS derivatives of glutarate, pimelate, cyclohex-1-ene carboxylate, benzoate, and cyclohexane carboxylate each increased by +1 mass unit, suggesting that carboxylation occurred after the synthesis of a four-carbon intermediate. With [1,2-(13)C]acetate and unlabeled crotonate, the m/z-15 ion of TMS-derivatized 3-hydroxybutyrate, acetoacetate, and glutarate each increased by +0, +2, and +4 mass units, respectively, and the m/z-15 ion of TMS-derivatized pimelate, cyclohex-1-ene carboxylate, benzoate, cyclohexane carboxylate, and 2-hydroxycyclohexane carboxylate each increased by +0, +2, +4, and +6 mass units. The data are consistent with a pathway for cyclohexane carboxylate formation involving the condensation of two-carbon units derived from crotonate degradation with CO2 addition, rather than the use of the intact four-carbon skeleton of crotonate.     

Heterotrophic nitrification and aerobic denitrification inAlcaligenes faecalis strain TUD

Heterotrophic nitrification and aerobic and anaerobic denitrification byAlcaligenes faecalis strain TUD were studied in continuous cultures under various environmental conditions. Both nitrification and denitrification activities increased with the dilution rate. At dissolved oxygen concentrations above 46% air saturation, hydroxylamine, nitrite and nitrate accumulated, indicating that both the nitrification and denitrification were less efficient. The overall nitrification activity was, however, essentially unaffected by the oxygen concentration. The nitrification rate increased with increasing ammonia concentration, but was lower in the presence of nitrate or nitrite. When present, hydroxylamine, was nitrified preferentially. Relatively low concentrations of acetate caused substrate inhibition (K_I=109 M acetate). Denitrifying or assimilatory nitrate reductases were not detected, and the copper nitrite reductase, rather than cytochrome cd, was present. Thiosulphate (a potential inhibitor of heterotrophic nitrification) was oxidized byA. faecalis strain TUD, with a maximum oxygen uptake rate of 140–170nmol O₂·min^-1·mg prot^-1. Comparison of the behaviour ofA. faecalis TUD with that of other bacteria capable of heterotrophic nitrification and aerobic denitrification established that the response of these organisms to environmental parameters is not uniform. Similarities were found in their responses to dissolved oxygen concentrations, growth rate and ammonia concentration. However, they differed in their responses to externally supplied nitrite and nitrate.     

Anaerobic degradation of sorbic acid by sulfate-reducing and fermenting bacteria: pentanone-2 and isopentanone-2 as byproducts

Strictly anaerobic bacteria were enriched and isolated from freshwater sediment sources in the presence and absence of sulfate with sorbic acid as sole source of carbon and energy. Strain WoSo1, a Gram-negative vibrioid sulfate-reducing bacterium which was assigned to the species Desulfoarculus (formerly Desulfovibrio) baarsii oxidized sorbic acid completely to CO₂ with concomitant stoichiometric reduction of sulfate to sulfide. This strain also oxidized a wide variety of fatty acids and other organic compounds. A Gram-negative rod-shaped fermenting bacterium, strain AmSo1, fermented sorbic acid stoichiometrically to about equal amounts of acetate and butyrate. At concentrations higher than 10 mM, sorbic acid fermentation led to the production of pentanone-2 and isopentanone-2 (3-methyl-2-butanone) as byproducts. Strain AmSo1 fermented also crotonate and 3-hydroxybutyrate to acetate and butyrate, and hexoses to acetate, ethanol, hydrogen, and formate. The guanine-plus-cytosine content of the DNA was 41.8±1.0 mol%. Sorbic acid at concentrations higher than 5 mM inhibited growth of this strain while strain WoSo1 tolerated sorbic acid up to 10 mM concentration.     

Acetate and carbon dioxide assimilation by Desulfovibrio vulgaris (Marburg), growing on hydrogen and sulfate as sole energy source

Desulfovibrio vulgaris (Marburg) was grown on hydrogen plus sulfate as sole energy source and acetate plus CO₂ as the sole carbon sources. The incorporation of U-¹⁴C acetate into alanine, aspartate, glutamate, and ribose was studied. The labelling data show that alanine is synthesized from one acetate (C-2 + C-3) and one CO₂ (C-1), aspartate from one acetate (C-2 + C-3) and two CO₂ (C-1 + C-4), glutamate from two acetate (C-1–C-4) and one CO₂ (C-5), and ribose from 1.8 acetate and 1.4 CO₂. These findings indicate that in Desulfovibrio vulgaris (Marburg) pyruvate is formed via reductive carboxylation of acetyl-CoA, oxaloacetate via carboxylation of pyruvate or phosphoenol pyruvate, and -ketoglutarate from oxaloacetate plus acetyl-CoA via citrate and isocitrate. Since C-5 of glutamate is derived from CO₂, citrate must have been formed via a (R)-citrate synthase rather than a(S)-citrate synthase. The synthesis of ribose from 1.8 mol of acetate and 1.4 mol of CO₂ excludes the operation of the Calvin cycle in this chemolithotrophically growing bacterium.     

Carbon monoxide pathway enzyme activities in a thermophilic anaerobic bacterium grown acetogenically and in a syntrophic acetate-oxidizing coculture

We recently isolated an acetate-oxidizing rodshaped eubacterium (AOR) which was capable of oxidizing acetate to CO₂ when grown in coculture with the hydrogenotrophic methanogen Methanobacterium sp. strain THF. The AOR was also capable of growing axenically on H₂CO₂ which it converted to acetate. Previous results for the acetate oxidizing coculture showed isotopic exchange between acetate and CO₂, suggesting that the AOR was using a pathway for acetate oxidation resembling a reveral of the acetogenic (carbon monoxide) pathway. In this study, it was found that production of ¹⁴CO₂ from ¹⁴CH₃COO^- by the coculture was inhibited by 200 M cyanide, while methanogenesis from H₂–CO₂ was unaffected, implying the involvement of carbon monoxide dehydrogenase (CODH) in acetate oxidation. CODH was present at 0.055 mol methyl viologen reduced min^-1 mg^-1 protein in extracts of Methanobacterium sp. strain THF, but was present in higher levels in the acetate oxidizing coculture and in the AOR grown axenically and on H₂–CO₂ (2.0 and 6.4 mol min^-1 mg^-1 protein respectively). Anaerobic activity stains for CODH in native polyacrylamide gels from the AOR coculture showed components co-migrating with bands from both organisms, as well as an additional band in extracts of the coculture. Formate dehydrogenase (FDH) was present in both the AOR coculture and monoculture but not in extracts of H₂–CO₂ grown cells of Methanobacterium sp. strain THF. Formyltetrahydrofolate (FTHF) synthetase was not detectable in extracts of the AOR monoculture or coculture, although it was found in high amounts in extracts of H₂–CO₂ grown cells of the thermophilic acetogen Acetogenium kivui. Extracts of H₂–CO₂ grown cells of the AOR showed a fluorescence spectrum typical of pterin derivatives. Bioassay for folates showed levels to be at anabolic rather than catabolic levels. It is possible that the AOR uses pterins distinct from folate for catabolism. Isocitrate dehydrogenase, a citric acid cycle enzyme, was also present in the AOR, but at anabolic levels and -ketoglutarate dehydrogenase was not detectable.Abbreviations (AOR) acetate-oxidizing rod - (CODH) carbon monoxide dehydrogenase - (FDH) formate dehydrogenase - (FTHF) formyltetrahydrofolate