Methanofuran (carbon dioxide reduction factor), a formyl carrier in methane production from carbon dioxide in Methanobacterium

Methanofuran (carbon dioxide reduction factor) became labeled when incubated in cell extracts of Methanobacterium under hydrogen and 14CO2 in the absence of methanopterin. Proton NMR spectroscopy revealed that a formyl group was bound to the primary amine of methanofuran. [14C]Formylmethanofuran was enzymically converted to 14CH4 in the presence of CH3-S-CoM [2-(methylthio)ethanesulfonic acid], hydrogen, and methanopterin, establishing the formyl moiety as an intermediate in methanogenesis. In the absence of methanopterin, a substantial portion of the formyl label was oxidized to 14CO2 rather than reduced to 14CH4, consistent with a model in which the C1 intermediate is first bound to methanofuran and then to methanopterin, during its reduction. When CH3-S-CoM was replaced by HS-CoM (2-mercaptoethanesulfonic acid), most of the formyl label was oxidized to 14CO2, indicating that methyl group reduction by the CH3-S-CoM methylreductase is required for the conversion of formylmethanofuran to methane.     

Methanopterin and methanogenic bacteria

Methanogenic bacteria comprise a selected group of microorganisms that derive their energy for growth from the hydrogen-dependent reduction of CO2 to methane or the disproportionation of reduced one-carbon compounds and acetate to CO2 and methane. In the reduction and oxidation steps at the formyl, hydroxymethyl and methyl level the one-carbon unit remains bound to the reduced form of methanopterin, a pterin derivative typical of methanogenic bacteria. In addition, the reduced methanopterin, 5,6,7,8-tetrahydromethanopterin, is involved in a number of anabolic reactions. Methanopterin is structurally and functionally the counterpart of folic acid found in other organisms. In this review the occurrence and properties of methanopterin and its derivatives, as well as the biosynthesis and the role in the different catabolic and anabolic reactions are discussed against the background of folic acid biochemistry.     

The bioenergetics of methanogenesis

The reduction of CO2 or any other methanogenic substrate to methane serves the same function as the reduction of oxygen, nitrate or sulfate to more reduced products. These exergonic reactions are coupled to the production of usable energy generated through a charge separation and a protonmotive-force-driven ATPase. For the understanding of how methanogens derive energy from C-1 unit reduction one must study the biochemistry of the chemical reactions involved and how these are coupled to the production of a charge separation and subsequent electron transport phosphorylation. Data on methanogenesis by a variety of organisms indicates ubiquitous use of CH3-S-CoM as the final electron acceptor in the production of methane through the methyl CoM reductase and of 5-deazaflavin as a primary source of reducing equivalents. Three known enzymes serve as catalysts in the production of reduced 5-deazaflavin: hydrogenase, formate dehydrogenase and CO dehydrogenase. All three are potential candidates for proton pumps. In the organisms that must oxidize some of their substrate to obtain electrons for the reduction of another portion of the substrate to methane (e.g., those using formate, methanol or acetate), the latter two enzymes may operate in the oxidizing direction. CO2 is the most frequent substrate for methanogenesis but is the only substrate that obligately requires the presence of H2 and hydrogenase. Growth on methanol requires a B12-containing methanol-CoM methyl transferase and does not necessarily need any other methanogenic enzymes besides the methyl-CoM reductase system when hydrogenase is present. When bacteria grow on methanol alone it is not yet clear if they get their reducing equivalents from a reversal of methanogenic enzymes, thus oxidizing methyl groups to CO2. An alternative (since these and acetate-catabolizing methanogens possess cytochrome b) is electron transport and possible proton pumping via a cytochrome-containing electron transport chain. Several of the actual components of the methanogenic pathway from CO2 have been characterized. Methanofuran is apparently the first carbon-carrying cofactor in the pathway, forming carboxy-methanofuran. Formyl-FAF or formyl-methanopterin (YFC, a very rapidly labelled compound during 14C pulse labeling) has been implicated as an obligate intermediate in methanogenesis, since methanopterin or FAF is an essential component of the carbon dioxide reducing factor in dialyzed extract methanogenesis. FAF also carries the carbon at the methylene and methyl oxidation levels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Methanogenesis involving a novel carrier of C1 compounds in Methanogenium tationis.

The pathway of CO2 reduction to methane in Methanogenium tationis and Methanogenium thermophilicum is similar to that observed in other methanogens. In M. tationis a novel pterin, tatiopterin, is present. This pterin appears to be a structural and functional analog of methanopterin and sarcinapterin. Folate could not substitute for tatiopterin.     

Calcium-dependent adenylate cyclase from rat cerebral cortex: Activation by guanine nucleotides

The adenylate cyclase activity of a participate preparation of rat cerebral cortex is composed of at least two contributing components, one of which requires a Ca²⁺-dependent regulator protein (CDR) for activity (Brostrom, C. O., Brostrom, M. A., and Wolff, D. J. (1977) J. Biol. Chem.252, 5677–5685). Each of these components of the activity was activated by GTP and its synthetic analog, 5-guanylylimidodiphosphate (Gpp(NH)p). The component of the adenylate cyclase activity which did not respond to CDR (CDR-independent activity) was stimulated approximately 60% by 100 μm GTP and 3.5-fold by 100 μm Gpp(NH)p. Concentrations of GTP required for maximal activation of the CDR-dependent adenylate cyclase component decreased as CDR concentrations in the assay were increased. Similarly, GTP pr Gpp(NH)p lowered the concentration of CDR required to produce half-maximal activation of this enzyme form. At saturating CDR concentrations, however, increases in activity were not observed with the addition of these nucleotides. The CDR-dependent component responded biphasically (activation followed by inhibition) to increasing free Ca²⁺ concentrations; both phases of this response occurred at lower free Ca²⁺ concentrations with GTP present in the assay. The concentration of chlorpromazine which inhibited activation of adenylate cyclase by CDR was elevated when GTP was present. The CDR-dependent form of activity, which is stabilized by CDR to thermal inactivation, was also stabilized by Gpp(NH)p. The increase in stability produced by Gpp(NH)p did not require the presence of CDR, and stabilization with both Gpp(NH)p and CDR was greater than that obtained with either Gpp(NH)p or CDR alone.     

Observation of pheophytin reduction in photosystem two reaction centers using femtosecond transient absorption spectroscopy.

Photosystem two reaction centers have been studied using a sensitive femtosecond transient absorption spectrometer. Measurements were performed at 295 K using different excitation wavelengths and excitation intensities which are shown to avoid multiphoton absorption by the reaction centers. Analyses of results collected over a range of time scales and probe wavelengths allowed the resolution of two exponential components in addition to those previously reported [Durrant, J. R., Hastings, G., Hong, Q., Barber, J., Porter, G., & Klug, D. R. (1992) Chem. Phys. Lett. 188, 54-60], plus the long-lived radical pair itself. A 21-ps component was observed. The process(es) responsible for this component was (were) found to produce bleaching of a pheophytin ground-state absorption band at 545 nm and the simultaneous appearance of a pheophytin anion absorption band at 460 nm resulting in a transient spectrum which was that of the radical pair P680+Ph-. This component is assigned to the production of reduced pheophytin. A lower limit of 60% of the final pheophytin reduction was found to occur at this rate. Despite subtle differences in transient spectra, the lifetime and yield of this pheophytin reduction are essentially independent of excitation wavelength within the signal to noise limitations of these experiments. A long-lived species was also observed. This species is produced by those processes which result in the 21-ps component, and it has a spectrum which is found to be independent of excitation wavelength. This spectrum is characteristic of the primary radical pair state P680+Ph-. In addition, a 200-ps component was found which is tentatively assigned to a slow energy-transfer/trapping process. This component was absent if P680 was excited directly and is therefore not integral to primary radical pair formation. Overall, it is concluded that the rate of pheophytin reduction is limited to (21 ps)-1, even when P680 is directly excited.     

Resolution of the methane mono-oxygenase of Methylococcus capsulatus (Bath) into three components. Purification and properties of component C, a flavoprotein.

1. Ion-exchange chromatography resolves the methane mono-oxygenase from soluble extracts of Methylococcus capsulatus (Bath) into three fractions. 2. Fractions A and B are comparatively stable at 0 degrees C, whereas fraction C is very unstable unless kept in the presence of sodium thioglycollate (1-10 mM) or dithiothreitol (5-10mM). 3. The active component from fraction C was purified some 80-fold. 4. Purified component C has mol. wt. 42000. Its solutions are yellow with absorption maxima at 270 and 465 nm and a shoulder at 395 nm. The 465 nm peak is abolished by reduction with NADH or sodium dithionite, or by photoreduction in the presence of EDTA. A new spectral species, probably a neutral flavin semiquinone, is observed on partial reduction of component C. 5. No copper was detected in samples of purified component C, but the protein contains 1.3-1.5 atoms of iron/molecule. 6. On boiling, component C releases a yellow-green fluorescent material that has been identified as FAD from its absorption and fluorescence spectra and by t.l.c. 7. Component C contains 1 mol of FAD/mol of protein.     

Purification and characterization of a new cationic peroxidase from fresh flowers of Cynara scolymus L

A basic heme peroxidase isoenzyme (AKPC) has been purified to homogeneity from artichoke flowers (Cynara scolymus L.). The enzyme was shown to be a monomeric glycoprotein, M(r)=42300+/-1000, (mean+/-S.D.) with an isoelectric point >9. The native enzyme exhibits a typical peroxidase ultraviolet-visible spectrum with a Soret peak at 404 nm (epsilon=137,000+/-3000 M(-1) cm(-1)) and a Reinheitzahl (Rz) value (A(404nm)/A(280nm)) of 3.8+/-0.2. The ultraviolet-visible absorption spectra of compounds I, II and III were typical of class III plant peroxidases but unlike horseradish peroxidase isoenzyme C, compound I was unstable. Resonance Raman and UV-Vis spectra of the ferric form show that between pH 5.0 and 7.0 the protein is mainly 6 coordinate high spin with a water molecule as the sixth ligand. The substrate-specificity of AKPC is characteristic of class III (guaiacol-type) peroxidases with chlorogenic and caffeic acids, that are abundant in artichoke flowers, as particularly good substrates at pH 4.5. Ferric AKPC reacts with hydrogen peroxide to yield compound I with a second-order rate constant (k(+1)) of 7.4 x 10(5) M(-1) s(-1) which is significantly slower than that reported for most other class III peroxidases. The reaction of ferric and ferrous AKPC with nitric oxide showed a potential use of this enzyme for quantitative spectrophotometric determination of NO and as a component of novel NO sensitive electrodes.     

Analyses of absorption and fluorescence spectra of water-soluble chlorophyll proteins, pigment system II particles and chlorophyll a in diethylether solution by the curve-fitting method.

Absorption and fluorescence spectra in the red region of water-soluble chlorophyll proteins, Lepidium CP661, CP663 and Brassica CP673, pigment System II particles of spinach chloroplasts and chlorophyll a in diethylether solution at 25 degrees C were analyzed by the curve-fitting method (French, C.S., Brown, J.S. and Lawrence, M.C. (1972) Plant Physiol 49, 421--429). It was found that each of the chlorophyll forms of the chlorophyll proteins and the pigment System II particles had a corresponding fluorescence band with the Stokes shift ranging from 0.6 to 4.0 nm. The absorption spectrum of chlorophyll a in diethylether solution was analyzed to one major band with a peak at 660.5 nm and some minor bands, while the fluorescence spectrum was analyzed to one major band with a peak at 664.9 nm and some minor bands. A mirror image was clearly demonstrated between the resolved spectra of absorption and fluorescence. The absorption spectrum of Lepidium CP661 was composed of a chlorophyll b form with a peak at 652.8 nm and two chlorophyll a forms with peaks at 662.6 and 671.9 nm. The fluorescence spectrum was analyzed to five component bands. Three of them with peaks at 654.8, 664.6 and 674.6 nm were attributed to emissions of the three chlorophyll forms with the Stokes shift of 2.0--2.7 nm. The absorption spectrum of Brassica CP673 had a chlorophyll b form with a peak at 653.7 nm and four chlorophyll a forms with peaks at 662.7, 671.3, 676.9 and 684.2 nm. The fluorescence spectrum was resolved into seven component bands. Four of them with peaks at 666.7, 673.1, 677.5 and 686.2 nm corresponded to the four chlorophyll a forms with the Stokes shift of 0.6--4.0 nm. The absorption spectrum of the pigment System II particles had a chlorophyll b form with a peak at 652.4 nm and three chlorophyll a forms with peaks at 662.9, 672.1 and 681.6 nm. The fluorescence spectrum was analyzed to four major component bands with peaks at 674.1, 682.8, 692.0 and 706.7 nm and some minor bands. The former two bands corresponded to the chlorophyll a forms with peaks at 672.1 and 681.6 nm with the Stokes shift of 2.0 and 1.2 nm, respectively. Absorption spectra at 25 degrees C and at --196 degrees C of the water-soluble chlorophyll proteins were compared by the curve-fitting methods. The component bands at --196 degrees C were blue-shifted by 0.8--4.1 nm and narrower in half widths as compared to those at 25 degrees C.     

Methane monooxygenase: purification and properties of flavoprotein component

An anaerobic procedure was developed for the purification of the flavin:NADH oxidoreductase (flavoprotein) component of methane monooxygenase to homogeneity. The molecular weight of the flavoprotein determined by gel filtration was about 40,000, and by sedimentation equilibrium analysis, about 38,000. The purified flavoprotein is a monomeric protein with a sedimentation constant (S20,W) value of about 2.1 S. The absorption spectrum of the flavoprotein has a peak at 460 nm and shoulder at 395 nm. The fluorescent excitation and emission spectra of the fluorescent component of flavoprotein had peaks at 450, 370, and 530 nm, respectively. A FAD was identified as a prosthetic group of flavoprotein by thin-layer chromatography. The flavoprotein contained about 1 mol of FAD and 2 mol each of iron and acid-labile sulfide per mole of protein. The flavoprotein was directly reduced by NADH under anaerobic conditions. The formation of neutral flavin semiquinone was detected during anaerobic titration of flavoprotein by NADH and also as a free radical signal at a g value of 2.004 by EPR spectroscopy. The iron sulfur cluster has g values of 2.04, 1.96, and 1.87, yielding a g average of 1.96, characteristic of a Fe2S2 center. Antibody prepared against the flavoprotein reacted with flavoprotein and inhibited methane monooxygenase activity.     

Coenzymes of methanogenesis from hydrogen and carbon dioxide

Methanogenic bacteria gain their energy for growth from the conversion of a number of simple carbon compounds to methane. With a few exceptions all species known to date are able to reduce CO₂ at which hydrogen acts as the electron donor. The reduction of CO₂ can formally be considered to proceed through the formyl, the formaldehyde and the methyl level of reduction. These C₁-units do not occur as free intermediates, but they remain bound to a number of unique coenzymes during the process. In this paper a survey is given of the structures and functions of these compounds; it deals with methanopterin derivatives, carbon dioxide reduction (CDR) factor, factor F₄₃₀ and coenzyme M derivatives. A model of the process of methanogenesis that integrates previous ones and that allocates a function to the various coenzymes is presented.This paper is adapted from a treatise by the same author, entitled Coenzymes of methanogenesis. that was awarded the Kluyver prize 1984 by the Netherlands Society for Microbiology.     

Analyses of absorption and fluorescence spectra of water-soluble chlorophyll proteins,pigment System II particles and chlorophyll a in diethylether solution by the curve-fitting method

Absorption and fluorescence spectra in the red region of water-soluble chlorophyll proteins, Lepidium CP661, CP663 and Brassica CP673, pigment System II particles of spinach chloroplasts and chlorophyll a in diethylether solution at 25°C were analyzed by the curve-fitting method (French, C.S., Brown, J.S. and Lawrence, M.C. (1972) Plant Physiol. 49, 421–429). It was found that each of the chlorophyll forms of the chlorophyll proteins and the pigment System II particles had a corresponding fluorescence band with the Stokes shift ranging from 0.6 to 4.0 nm.The absorption spectrum of chlorophyll a in diethylether solution was analyzed to one major band with a peak at 660.5 nm and some minor bands, while the fluorescence spectrum was analyzed to one major band with a peak at 664.9 nm and some minor bands. A mirror image was clearly demonstrated between the resolved spectra of absorption and fluorescence. The absorption spectrum of Lepidium CP661 was composed of a chlorophyll b form with a peak at 652.8 nm and two chlorophyll a forms with peaks at 662.6 and 671.9 nm. The fluorescence spectrum was analyzed to five component bands. Three of them with peaks at 654.8, 664.6 and 674.6 nm were attributed to emissions of the three chlorophyll forms with the Stokes shift of 2.0–2.7 nm. The absorption spectrum of Brassica CP673 had a chlorophyll b form with a peak at 653.7 nm and four chlorophyll a forms with peaks at 662.7, 671.3, 676.9 and 684.2 nm. The fluorescence spectrum was resolved into seven component bands. Four of them with peaks at 666.7, 673.1, 677.5 and 686.2 nm corresponded to the four chlorophyll a forms with the Stokes shift of 0.6–4.0 nm. The absorption spectrum of the pigment System II particles had a chlorophyll b form with a peak at 652.4 nm and three chlorophyll a forms with peaks at 662.9, 672.1 and 681.6 nm. The fluorescence spectrum was analyzed to four major component bands with peaks at 674.1, 682.8, 692.0 and 706.7 nm and some minor bands. The former two bands corresponded to the chlorophyll a forms with peaks at 672.1 and 681.6 nm with the Stokes shift of 2.0 and 1.2 nm, respectively.Absorption spectra at 25°C and at ?196°C of the water-soluble chlorophyll proteins were compared by the curve-fitting method. The component bands at ?196°C were blue-shifted by 0.8–4.1 nm and narrower in half widths as compared to those at 25°C.     

Carbon monoxide and skate gastric cells: respiration and action spectrum

The rate of O₂ uptake in cells isolated from the skate gastric mucosa was determined as a function of the ratio [CO]/[O₂] by an O₂ electrode method. Skate cells are five times less sensitive to the effects of CO than yeast, which was used as a normal control cell. In both cell types, CO inhibition can be partially reversed by white light. Therefore, the action spectrum for the relief of CO inhibition was determined for the two cell types. In yeast, the alpha peak of the action spectrum for photodissociation of the CO-oxidase complex (which is the alpha peak of the absorption spectrum of this complex) is found at 590 nm, as expected from prior work on this oxidase. In skate gastric mucosa cells, the corresponding peak is at 580 nm, and these two peaks clearly represent different CO complexes. These observations help to explain the lack of CO inhibition of acid secretion in the skate gastric mucosa, and the observation of a non-standard terminal oxidase in the absorption spectrum of this tissue.Abbreviations DNP 2, 4-dinitrophenol - Kl_M Michaelis constant - ACD analog to digital converter - K _i dissociation coefficient for enzyme-inhibitor complex     

Carbon monoxide:methylene blue oxidoreductase from Pseudomonas carboxydovorans.

The enzyme carbon monoxide:methylene blue oxidoreductase from CO autotrophically grown cells of Pseudomonas carboxydovorans strain OM5, was purified to homogeneity. The enzyme was obtained in 26% yield and was purified 36-fold. The enzyme was stable for at least 6 days, had a molecular weight of 230,000, gave a single protein and activity band on polyacrylamide gel electrophoresis, and was homogeneous by the criterion of sedimentation equilibrium. Sodium dodecyl sulfate gel electrophoresis revealed a single band of molecular weight 107,000. Carbon monoxide:methylene blue oxidoreductase did not catalyze reduction of pyridine or flavin nucleotides but catalyzed the oxidation of CO to CO2 in the presence of methylene blue, thionine, toluylene blue, dichlorophenolindophenol, or pyocyanine under strictly anaerobic conditions. The visible spectrum revealed maxima at 405 and 470 nm. The millimolar extinction coefficients were 43.9 (405 nm) and 395.5 (275 nm), respectively. Absorption at 470 nm decreased in the presence of dithionite, and the spectrum was not affected by the substrate CO. Maximum reaction rates were found at pH 7.0 and 63 degrees C; temperature dependence followed the Arrhenius equation, with an activation energy (delta H degree) of 36.8 kJ/mol (8.8 kcal/mol). The apparent Km was 53 microM for CO. The purified enzyme was incapable of oxidizing methane, methanol, or formaldehyde in the presence of methylene blue as electron acceptor.     

Purification and characterization of component A of the methane monooxygenase from Methylococcus capsulatus (Bath)

Methylococcus capsulatus (Bath) possesses a multi-component methane monooxygenase which catalyzes in vivo the conversion of methane to methanol. Component A of this enzyme system, believed to be the oxygenase component, has been purified to near homogeneity (95%). The native protein has a molecular weight of approximately 210,000 and is comprised of three subunits of Mr = 54,000, 42,000, and 17,000, which appear to be present in stoichiometric amounts suggesting an alpha 2, beta 2, gamma 2 arrangement in the native protein. Purified preparations of the protein are virtually colorless and examination of the uv/visible absorption spectrum revealed a peak around 280-290 nm and thereafter a steady decrease in absorbance to longer wavelengths. The ESR spectrum of the oxidized protein gave a signal at g = 4.3, presumably due to rhombic iron, and a radical signal at g = 2.01. Upon reduction with dithionite, a signal at g = 1.934 appeared. Chemical analyses of our purified preparations revealed the presence of iron (2.3 mol/mol) and zinc (0.2-0.5 mol/mol): molybdenum, copper, nickel, heme, and acid-labile sulfur were all virtually absent. On ultra thin layer isoelectric focusing, purified component A was judged to have a pI between 5.0 and 5.1. Extracts prepared from a variety of other methanotrophs failed to show any cross-reaction to antibody raised against M. capsulatus component A.     

A rapid spectrophotometric assay for ferrochelatase activity in preparations containing much endogenous hemoglobin and its application to soybean root-nodule preparations.

A simple and rapid spectrophotometric assay for ferrochelatase (EC 4.99.1.1) activity is described which is suitable for use with enzyme preparations containing large amounts of hemoglobin. In this method mesoporphyrin IX is used as substrate and the product, mesoheme IX, is measured by recording the reduced minus the oxidized pyridine hemochrome spectrum. Pyridine mesohemochrome has an α peak at 547 nm and a trough at 531 nm while the α peak and trough of pyridine protohemochrome (from hemoglobin) are at 557 and 541 mm, respectively. Thus the contribution of the protohemochrome to E_1cm^547-531nm, which can be allowed for, is small, and so the method gives very reliable determinations of the amounts of mesoheme IX formed.By means of this assay, it was shown that in excess of 90% of the ferrochelatase activity of soybean root-nodules is present in the bacteroid cells and less than 10% in the plant mitochondria: No ferrochelatase activity could be detected in the soluble plant fraction.     

Investigation of nickel supported catalysts for the upgrading of brown peat derived gasification products

A gasification test rig was designed in which peat was gasified under nitrogen over a temperature range 25-550 degrees C at 5 degrees C min(-1). The gasification unit resulted in 35.5 wt% of the carbon present in the peat being converted to a volatile fraction. The volatile fraction was transferred to a secondary catalytic reforming reactor at 800 degrees C. The thermal effect of the second reactor resulted in an increase in the CO, CO2 and CH4 content of the volatile fraction, a syngas ratio of 0.75 and a higher heating value (HHV) of 26.5 MJ kg(-1). Several nickel-supported catalysts were investigated with the intention that they should give an increase in the conversion of the condensable hydrocarbons in the volatile fraction to CO, CO2 and CH4, and a resultant gas stream suitable for use in an integrated gasification combined cycle plant (IGCC) (i.e. syngas ratio 2:1, low methane content and better HHV). Alumina-supported nickel catalysts investigated gave the highest activities and co-precipitated Ni/Al catalysts were most active. A Ni/Al 3:17 catalyst increased the conversion of the hydrocarbons to 91.5%, gave a syngas ratio of 1.81:1, increased the HHV by a factor of 5.3 and completely eliminated methane from the gas stream.     

Elucidation of the structure of methanopterin, a coenzyme from Methanobacterium thermoautotrophicum, using two-dimensional nuclear-magnetic-resonance techniques

Methanopterin is a coenzyme involved in methanogenesis. From 2 kg wet cells of Methanobacterium thermoautotrophicum about 35 mumol methanopterin were isolated. The structure of this compound was elucidated by various two-dimensional nuclear-magnetic-resonance techniques. Methanopterin was identified as N-[1'-(2"-amino-4"-hydroxy-7" - methyl-6"- pteridinyl) ethyl]-4-[2',3',4',5'- tetrahydroxypent-1'- yl (5' leads to 1") O-alpha-ribofuranosyl-5"-phosphoric acid] aniline, in which the phosphate group is esterified with alpha-hydroxyglutaric acid. The molecular formula of the sodium salt of methanopterin at pH 7.0 is C30H38O16N6PNa3 X chiH2O (chi is about 4). The anhydrous sodium salt of methanopterin has a molecular mass of 838.60 Da and the molar absorption coefficient at 342 nm is 7.4 mM-1 cm-1 at pH 7.0.     

Purification and properties of a cytochrome b560-d complex, a terminal oxidase of the aerobic respiratory chain of Photobacterium phosphoreum

A cytochrome b560-d complex, a terminal oxidase in the respiratory chain of Photobacterium phosphoreum grown under aerobic conditions, was purified to near homogeneity. The purified oxidase complex is composed of equimolar amounts of two polypeptides with molecular weights of 41,000 and 54,000, as determined by gel electrophoresis in the presence of sodium dodecyl sulfate. It contains 10.2 nmol of protoheme and 22.5 nmol of iron/mg of protein. The enzyme is a "cytochrome bd-type oxidase," showing absorption peaks at 560 and 625 nm in its reduced minus oxidized difference spectrum at 77K. This oxidase combined with CO, and its CO difference spectrum at room temperature in the Soret region showed a peak at 418 nm and a trough at 434 nm. In addition, a trough at 560 nm (cytochrome b), and a trough at 620 nm and a peak at 639 nm (cytochrome d) were observed in the CO-binding spectrum. This cytochrome b560-d complex catalyzed the oxidation of ubiquinol-1 and ascorbate in the presence of N,N,N',N'-tetramethyl-p-phenylenediamine dihydrochloride or phenazine methosulfate. The oxidase activity required phospholipids and was inhibited by the respiratory inhibitors, KCN and NaN3, and the divalent cation, ZnSO4. Formation of a membrane potential by the cytochrome b560-d complex reconstituted into liposomes was observed with the fluorescent dye, 3,3'-dipropylthiodicarbocyanine iodide, on the addition of ubiquinol-1, showing that the enzyme provided a coupling site for oxidative phosphorylation.     

Targeting methanopterin biosynthesis to inhibit methanogenesis

This paper describes the design, synthesis, and successful employment of inhibitors of 4-(beta-D-ribofuranosyl)aminobenzene-5'-phosphate (RFA-P) synthase, which catalyzes the first committed step in the biosynthesis of methanopterin, to specifically halt the growth of methane-producing microbes. RFA-P synthase catalyzes the first step in the synthesis of tetrahydromethanopterin, a key cofactor required for methane formation and for one-carbon transformations in methanogens. A number of inhibitors, which are N-substituted derivatives of p-aminobenzoic acid (pABA), have been synthesized and their inhibition constants with RFA-P synthase have been determined. Based on comparisons of the inhibition constants among various inhibitors, we propose that the pABA binding site in RFA-P synthase has a relatively large hydrophobic pocket near the amino group. These enzyme-targeted inhibitors arrest the methanogenesis and growth of pure cultures of methanogens. Supplying pABA to the culture relieves the inhibition, indicating a competitive interaction between pABA and the inhibitor at the cellular target, which is most likely RFAP synthase. The inhibitors do not adversely affect the growth of pure cultures of the bacteria (acetogens) that play a beneficial role in the rumen. Inhibitors added to dense ruminal fluid cultures (artificial rumena) halt methanogenesis; however, they do not inhibit volatile fatty acid (VFA) production and, in some cases, VFA levels are slightly elevated in the methanogenesis-inhibited cultures. We suggest that inhibiting methanopterin biosynthesis could be considered in strategies to decrease anthropogenic methane emissions, which could have an environmental benefit since methane is a potent greenhouse gas.