Mechanism of acetate synthesis from CO2 by Clostridium acidiurici.

Total synthesis of acetate from CO2 by Clostridium acidiurici during fermentations of hypoxanthine has been shown to involve synthesis of glycine from methylenetetrahydrofolate, CO2, and NH3. The glycine is converted to serine by the addition of methylenetetrahydrofolate, and the resulting serine is converted to pyruvate, which is decarboxylated to form acetate. Since CO2 is converted to methylenetetrahydrofolate, both carbons of the acetate are derived from CO2. The evidence supporting this pathway is based on (i) the demonstration that glycine decarboxylase is present in C. acidiurici, (ii) the fact that glycine is synthesized by crude extracts at a rate which is rapid enough to account for the in vivo synthesis of acetate from CO2, (iii) the fact that methylenetetrahydrofolate is an intermediate in the formation of both carbons of acetate from CO2, and (iv) the fact that the alpha carbon of glycine is the source of the carboxyl group of acetate. Evidence is presented that this synthesis of acetate does not involve carboxylation of a methyl corrinoid enzyme such as occurs in Clostridium thermoaceticum and Clostridium formicoaceticum. Thus, there are two different mechanisms for the total synthesis of acetate from CO2 by clostridia.     

Prebiotic synthesis in atmospheres containing CH4, CO,and CO2

The prebiotic synthesis of organic compounds using a spark discharge on various simulated primitive earth atmospheres at 25 degrees C has been studied. Methane mixtures contained H2 + CH4 + H2O + N2 + NH3 with H2/CH4 molar ratios from 0 to 4 and pNH3 = 0.1 torr. A similar set of experiments without added NH3 was performed. The yields of amino acids (1.2 to 4.7% based on the carbon) are approximately independent of the H2/CH4 ratio and whether NH3 was present, and a wide variety of amino acids are obtained. Mixtures of H2 + CO + H2O + N2 and H2 + CO2 + H2O + N2, with and without added NH3, all gave about 2% yields of amino acids at H2/CO and H2/CO2 ratios of 2 to 4. For a H2/CO2 ratio of 0, the yield of amino acids is extremely low (10(-3)%). Glycine is almost the only amino acid produced from CO and CO2 model atmospheres. These results show that the maximum yield is about the same for the three carbon sources at high H2/carbon ratios, but that CH4 is superior at low H2/carbon ratios. In addition, CH4 gives a much greater variety of amino acids than either CO or CO2. If it is assumed that an abundance of amino acids more complex than glycine was required for the origin of life, then these results indicate the requirement for CH4 in the primitive atmosphere.     

Tetrahydromethanopterin,a coenzyme involved in autotrophic acetyl coenzyme A synthesis from 2 CO2 in Methanobacterium

Methanobacterium thermoautotrophicum, a methane forming archaebacterium, grows autotrophically by synthesizing activated acetic acid from 2 CO₂. It is demonstrated in vitro that the methyl group of acetate is derived from methenyl tetrahydromethanopterin, which is known to be a one-carbon carrying coenzyme in CO₂ reduction to methane. The direct acetate precursors are suggested to be methyl tetrahydromethanopterin (“activated methanol”) and “activated carbon monoxide”.     

Autotrophic synthesis of activated acetic acid from two CO2 inMethanobacterium thermoautotrophicum

An in vitro system of autotropic synthesis of activated acetic acid from¹⁴CO₂ inMethanobacterium thermoautotrophicum was developed.

1. A recognized¹⁴CO₂-fixation product in vitro was activated [¹⁴C] acetic acid. It could be trapped enzymatically into citrate and released again as [¹⁴C] acetate by citrate synthase and citrate lyase, respectively.
2. The synthesis of both activated acetic acid and methane from CO₂ proceeded in parallel under a variety of conditions. Both of these processes were stimulated greatly and to the same extent by the addition of methyl coenzyme M to the assay.
3. Various inhibitors of methanogenesis tested also inhibited acetate synthesis, e.g. CH₂Cl₂, CHCl₃, CCl₄, N₂O, and bromoethane sulfonic acid. Cyanide specifically inhibited the synthesis of activated acetic acid, whereas methane formation was unaffected. Cyanide inhibition was relieved by adding CO, whereas the inhibition by the other compounds was not.

The data suggest: The product studied in vitro was acetyl CoA. Its synthesis involves intermediates of CO₂ reduction to methane. In addition, a cyanide-sensitive reaction is required which does not participate in CO₂ reduction to methane.     

Autotrophic synthesis of activated acetic acid from two CO2 inMethanobacterium thermoautotrophicum

A cell-free preparation of heterocysts from Anabaena variabilis showed high nitrogenase activities with several physiological electron donors, dependent on addition of an ATP-generating system. Light-induced acetylene reduction with the artificial electron donor to photosystem I, diaminodurol, exhibited the same light saturation as with hydrogen as donor. Inhibitors of electron flow through plastoquinone affected light-induced, hydrogen- or NADH-dependent nitrogenase activity in a similar way. Several uncoupling agents were without effect, indicating that energized membranes are not a prerequisite for nitrogen fixation. We conclude that NADH or hydrogen deliver electrons to nitrogenase via photosystem I and ferredoxin, feeding in at the plastoquinone site.In the light, addition of NADP induced a lag in H₂- or NADH-supported acetylene reduction apparently by competing with nitrogenase for electrons at the reducing side of photosystem I. Time reversal of this inibition reflects a regulation of photosystem I-dependent nitrogenase activity by the NADPH/NADP ratio in the cell. This was directly demonstrated by differently adjusted NADPH/NADP ratios.NADPH donates electrons to nitrogenase in the dark and in the light, the light reaction being DBMIB-sensitive. NADPH-supported acetylene reduction was inhibited by NADP. This inhibition was not reversed with time, pointing to an involvement of ferredoxin: NADP oxidoreductase (EC 1.18.1.2) in this pathway. Apparently, in the dark, this enzyme is able to directly reduce ferredoxin, whereas in the light electrons from NADPH first have to pass through photosystem I before reducing ferredoxin, hence nitrogenase.Intermediates of glycolysis, like glucose-6-phosphate, fructose-1,6-bisphosphate, and dihydroxyacetone phosphate supported nitrogenase activity in the dark, each with catalytic amounts of both NAD and NADP as equally effective cofactors.We conclude that in heterocysts electrons for nitrogen fixation are essentially supplied by dark reactions, mainly by glycolysis. NADH (and hydrogen) contribute electrons via photosystem I in the light, whereas the NADPH/NADP ratio regulates linear and cyclic electron flow at the reducing side of photosystem I to provide a ratio of ATP/electrons most effective for nitrogenase.Abbvreviations ATCC American Type Culture Collection - Diaminodurol (DAD) 2,3,5,6-tetramethyl-p-phenylenediamine dihydrochloride - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DNP-INT 2,4-dinitrophenyl ether of 2-iodo-4-nitrothymol - E Einstein (mol photons) - FNR ferredoxin - NADP oxidoreductase (EC 1.18.1.2) - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - Metronidazole 1-(2-hydroxyethyl)-2-methyl-5-nitroimidazole     

Measurement of bile acid synthesis by 14CO2: the metabolism of propionyl CoA.

The relationship between 14CO2 evolution from the catabolism of [26 or 2714C] cholesterol to bile acids was studied in rats with biliary fistulae. When equal quantities of [26 or 2714C] cholesterol and [414C] cholesterol were administered, there was a significant linear relationship between 14CO2 expiration in the breath and [414C] bile acid excreted in the bile. Bile acid synthesis calculated as the ratio of 14CO2: molar specific activity of biliary cholesterol correlated highly with biliary bile acid excretion in the bile acid depleted rat. Phenobarbital, a known inducer of gamma-amino levulenic acid formation from succinyl CoA did not alter the relationship between the 14CO2 estimation of bile acid synthesis and biliary bile acid excretion, indicating that the relationship between [26 or 2714C] cholesterol side chain cleavage and 14CO2 formation was not altered. Phenobarbital, however, did cause a reduction in bile acid synthesis measured by 14CO2 evolution and by biliary bile acid excretion. The 14CO2 method underestimated bile acid excretion. 8.7% in untreated and phenobarbital treated rats respectively. Since 11% of the radioactivity which was expired as 14CO2 was isolated as bile acids, radioactivity cleaved as [1 or 314C] propionyl CoA may enter cholesterol-bile acid biosynthesis resulting in the underestimation of bile acid synthesis. To test whether radioactivity from propionyl CoA enters steroid biosynthesis [114C] propionate and [214C] propionate were given to untreated biliary fistula rats and the biliary lipids excreted in 60 hours were analyzed. Incorporation of radioactivity into cholesterol and bile acids was greater after the administration of [214C] propionate than after [114C] propionate than after [114C] propionate, suggesting that radioactivity from propionyl CoA may enter steroid biosynthesis by metabolic events in which the methylene and carboxyl carbon atoms are differentiated. Although the use of 14CO2 expiration from [26 or 2714C] cholesterol catabolism underestimates the rate of bile acid synthesis, it should have many applications because of the constant relationship between 14CO2 formation and cholesterol side chain cleavage.     

Synthesis of biomolecules from N2, CO,and H2O by electric discharge

A model primitive gas containing a mixture of N₂, CO and water vapor over a water pool (300 mL, 37 °C) was subjected to electric discharges. The discharge vessel (7 L in volume) was equipped with a CO₂ absorber (The CO₂ being formed during the discharge), thus simulating possible absorption of CO₂ in the primitive ocean. The vessel also has a cold trap ( –15 °C), which protects the primary products against the further decomposition in the discharge phase by enabling these products to adhere to the trap. Since the partial pressures of CO and N₂ decreased at rates of 1.5–1.7 cmHg day^–1 and 0.1–0.2 cmHg day^–1, respectively, the gases were added at regular intervals. The solution was analyzed at regular intervals for HCN, HCHO and urea, and maximum concentrations of about 50, 2, and 140 mM were observed. The discharge phase was continued for 6 months. In the solution, glycine (5.6% yield based on the carbon), glycylglycine (0.64%), orotic acid (0.004%) and small amounts of the other amino acids were found.     

Redox-dependent CO2 reduction activity of CO dehydrogenase from Rhodospirillum rubrum.

Carbon monoxide dehydrogenase (CODH) from Rhodospirillum rubrum catalyzes both the oxidation of CO and the reduction of CO(2). Studies of the redox dependence of CO(2) reduction by R. rubrum CODH show that (1) CODH is unable to catalyze CO(2) reduction at potentials greater than -300 mV; (2) the maximum activity is observed at potentials less than -480 mV; and (3) the midpoint potential (E(m)) of the transition from minimum to maximum CO(2) reduction activity occurs at approximately -339 mV. These results indicate that the C(red1) state of R. rubrum CODH (E(m) = -110 mV; g(zyx)() = 2.03, 1.88, 1.71) is not competent to reduce CO(2). Nernst analyses suggest that the reduction of CODH from the C(red1) state to the CO(2)-reducing form (C(unc), g(zyx)() = 2.04, 1.93, 1.89; E < approximately -300 mV) of the enzyme is a one-electron process. For the entire redox range, viologens stimulate CO(2) reduction by CODH more than 50-fold, and it is proposed that viologens accelerate the redox equilibration of redox buffers and [Fe(4)S(4)](B) during catalysis.     

Enzymatic synthesis of formic acid from H2 and CO2 and production of hydrogen from formic acid

Whole cells of Alcaligenes eutrophus (as well as isolated P. oxalaticus formate dehydrogenase and A. eutrophus hydrogenase coupled via NAD(+) or methyl viologen) have been shown to produce H(2) from formic acid. Immobilization of the cells in kappacarrageenan gel greatly enhances their stability at room temperature. The rate of hydrogen production catalyzed by immobilized A. eutrophus has been studied as a function of the concentrations of the cells and formate and also pH. An inhibition by high concentrations of formate has been found. Immobilized cells were also capable of synthesizingformate from H(2) and bicarbonate. Yields of formate up to 30% have been obtained. The catalytic efficiency of immobilized A. eutrophus cells was compared with that of palladium adsorbed on activated carbon.     

Total Synthesis of Acetate from CO2 V. Determination by Mass Analysis of the Different Types of Acetate Formed from 13CO2 by Heterotrophic Bacteria

Mass analysis was used to determine the amount of acetate which is totally synthesized from (13)CO(2) during fermentations by Clostridium formicoaceticum, C. acidiurici, C. cylindrosporum, Butyribacterium rettgeri, and Diplococcus glycinophilus. In the fermentation of fructose by C. formicoaceticum, 27% of the acetate was found to be totally synthesized from CO(2), and the remaining acetate was unlabeled, having been formed from fructose. Evidence is presented that the purine-fermenting organisms, C. acidiurici and C. cylindrosporum, totally synthesized about 9% of the acetate from CO(2), and that the methyl group of an additional 9% was formed from CO(2). The remaining acetate was formed from the carbons of the purine and not via CO(2). It has been postulated that the fermentation of the purines and synthesis of acetate from CO(2) both occur via derivatives of tetrahydrofolate. Evidence is presented that a compartmentalization of these folate intermediates is required if both the purine degradation and the CO(2) utilization involve identical intermediates. Neither B. rettgeri nor D. glycinophilus incorporated sufficient (13)CO(2) into acetate to allow determination of the types of acetate by mass analysis, although they did incorporate labeled (14)CO(2) in both positions of acetate.     

Autotrophic synthesis of activated acetic acid from two CO2 in Methanobacterium thermoautotrophicum

In a previous study with Methanobacterium thermoautotrophicum evidence was presented that methanogenesis and autotrophic synthesis of activated acetic acid from CO₂ are linked processes. In this study one-carbon metabolism was investigated with growing cultures and in vitro.Serine was shown to be converted into glycine and activated formaldehyde, but only traces of label from [¹⁴C-3] of serine appeared in biosynthetic one-carbon positions. This seeming discrepancy could be explained if the same activated formaldehyde is an intermediate in biosynthesis and in methanogenesis from CO₂. This hypothesis was supported by demonstrating that [¹⁴C-3] of serine and [¹⁴C] formaldehyde were rapidly converted into methane, but a small portion of the label was also specifically incorporated into the methyl group of acetate. Methane and acetate synthesis in vitro were similarly stimulated by various compounds. These experiments indicate that the methyl of acetate and methane share common one-carbon precursor(s), i.e. methylene tetrahydromethanopterin, which can also be formed enzymatically from C-3 of serine or chemically from formaldehyde.Propyl iodide 20–40 M) and methyl iodide (1–3 M) completely inhibited growth in the dark. This effect was abolished by light. Methane formation was hardly affected. When ¹⁴CH₃I was applied at an only slightly inhibitory concentration, ¹⁴C was incorporated into the methyl of acetate. In vitro, similar effects on [¹⁴C] acetate formation from ¹⁴CO₂ or from [¹⁴C-3] of serine were observed, except that methyl iodide did not inhibit, but even stimulated acetate synthesis. These experiments indicate that a corrinoid is involved in acetate synthesis and probably not in methanogenesis from CO₂; the metal is light-reversibly alkylated and functions in methyl transfer to the acetate methyl.     

Organic acid production from CO2/H2 and CO/H2 by mixed-culture anaerobes

The gases CO, CO₂, and H₂ were used as substrates in anaerobic fermentations producing organic acids. Various mixed bacterial sources were used, including sewage sludge digester effluent, rabbit feces, and soil. Nonsterile microorganism selection was carried out using CO₂/H₂ and CO/H₂ as the primary carbon and energy sources. Cultures were grown in specially designed, high-pressure (to 70 psig) flasks. Methanogenic bacteria were eliminated from the cultures. Liquid products of the fermentations were acetic through caproic acids, with the even-numbered acids predominating. Carbon balances showed conclusively that acetic acid was formed from carbon contained in the CO or CO₂ feed gas. Measurements made included rates of acid product formation, cell density, and degree of gas utilization. Limited characterization of the microorganisms was also performed. Production of organic acids by mixed culture inocula from CO₂/H₂ or CO/H₂ had not been reported previously. Application of this work is to the production of organic chemicals from synthesis gas (SNG), produced by the gasification of fossil fuels (peat, lignite, and various ranks of coals), biomass (agricultural and forest residues, and various biomass crops grown expressly for energy recovery), and municipal solid waste.