7-mercaptoheptanoylthreonine Phosphate Research Articles

Thiol-Disulfide Exchange Kinetics and Redox Potential of the Coenzyme M and Coenzyme B Heterodisulfide, an Electron Acceptor Coupled to Energy Conservation in Methanogenic Archaea.

Methanogenic and methanotrophic archaea play important roles in the global carbon cycle by interconverting CO2 and methane. To conserve energy from these metabolic pathways that happen close to the thermodynamic equilibrium, specific electron carriers have evolved to balance the redox potentials between key steps. Reduced ferredoxins required to activate CO2 are provided by energetical coupling to the reduction of the high-potential heterodisulfide (HDS) of coenzyme M (2-mercaptoethanesulfonate) and coenzyme B (7-mercaptoheptanoylthreonine phosphate). While the standard redox potential of this important HDS has been determined previously to be -143 mV (Tietze et al. 2003 DOI: 10.1002/cbic.200390053), we have measured thiol disulfide exchange kinetics and reassessed this value by equilibrating thiol-disulfide mixtures of coenzyme M, coenzyme B, and mercaptoethanol. We determined the redox potential of the HDS of coenzyme M and coenzyme B to be -16.4±1.7 mV relative to the reference thiol mercaptoethanol (E0 '=-264 mV). The resulting E0 ' values are -281 mV for the HDS, -271 mV for the homodisulfide of coenzyme M, and -270 mV for the homodisulfide of coenzyme B. We discuss the importance of these updated values for the physiology of methanogenic and methanotrophic archaea and their implications in terms of energy conservation.

Observation of Organometallic and Radical Intermediates Formed during the Reaction of Methyl-Coenzyme M Reductase with Bromoethanesulfonate

Methyl-coenzyme M reductase (MCR) from methanogenic archaea catalyzes the final step of methane formation, in which methyl-coenzyme M (2-methylthioethanesulfonate, methyl-SCoM) is reduced with coenzyme B (N-(7-mercaptoheptanoyl)threonine phosphate, CoBSH) to form methane and the heterodisulfide CoBS-SCoM. The active dimeric form of MCR contains two Ni(I)-F(430) prosthetic groups, one in each monomer. This report describes studies of the reaction of the active Ni(I) state of MCR (MCR(red1)) with BES (2-bromoethanesulfonate) and CoBSH or its analogue, CoB(6)SH (N-(6-mercaptohexanoyl)threonine phosphate), by transient kinetic measurements using EPR and UV-visible spectroscopy and by global fits of the data. This reaction is shown to lead to the formation of three intermediates, the first of which is assigned as an alkyl-Ni(III) species that forms as the active Ni(I)-MCR(red1) state of the enzyme decays. Subsequently, a radical (MCR(BES) radical) is formed that was characterized by multifrequency electron paramagnetic resonance (EPR) studies at X- ( approximately 9 GHz), Q- ( approximately 35 GHz), and D- ( approximately 130 GHz) bands and by electron-nuclear double resonance (ENDOR) spectroscopy. The MCR(BES) radical is characterized by g-values at 2.00340 and 1.99832 and includes a strongly coupled nonexchangeable proton with a hyperfine coupling constant of 50 MHz. Based on transient kinetic measurements, the formation and decay of the radical coincide with a species that exhibits absorption peaks at 426 and 575 nm. Isotopic substitution, multifrequency EPR, and ENDOR spectroscopic experiments rule out the possibility that MCR(BES) is a tyrosyl radical and indicate that if a tyrosyl radical is formed during the reaction, it does not accumulate to detectable levels. The results provide support for a hybrid mechanism of methanogenesis by MCR that includes both alkyl-Ni and radical intermediates.

Novel Thiols of Prokaryotes

Glutathione metabolism is associated with oxygenic cyanobacteria and the oxygen-utilizing purple bacteria, but is absent in many other prokaryotes. This review focuses on novel thiols found in those bacteria lacking glutathione. Included are glutathione amide and its perthiol, produced by phototrophic purple sulfur bacteria and apparently involved in their sulfide metabolism. Among archaebacteria, coenzyme M (2-mercaptoethanesulfonic acid) and coenzyme B (7-mercaptoheptanoylthreonine phosphate) play central roles in the anaerobic production of CH4 and associated energy conversion by methanogens, whereas the major thiol in the aerobic phototrophic halobacteria is gamma-glutamylcysteine. The highly aerobic actinomycetes produce mycothiol, a conjugate of N-acetylcysteine with a pseudodisaccharide of glucosamine and myo-inositol, AcCys-GlcNalpha(1 --> 1)Ins, which appears to play an antioxidant role similar to glutathione. Ergothioneine, also produced by actinomycetes, remains a mystery despite many years of study. Available data on the biosynthesis and metabolism of these and other novel thiols is summarized and key areas for additional study are identified.

The F420H2 dehydrogenase from Methanosarcina mazei is a Redox-driven proton pump closely related to NADH dehydrogenases.

The F(420)H(2) dehydrogenase is part of the energy conserving electron transport system of the methanogenic archaeon Methanosarcina mazei Gö1. Here it is shown that cofactor F(420)H(2)-dependent reduction of 2-hydroxyphenazine as catalyzed by the membrane-bound enzyme is coupled to proton translocation across the cytoplasmic membrane, exhibiting a stoichiometry of 0.9 H(+) translocated per two electrons transferred. The electrochemical proton gradient thereby generated was shown to drive ATP synthesis from ADP + P(i). The gene cluster encoding the F(420)H(2) dehydrogenase of M. mazei Gö1 comprises 12 genes that are referred to as fpoA, B, C, D, H, I, J, K, L, M, N, and O. Analysis of the deduced amino acid sequences revealed that the enzyme is closely related to proton translocating NADH dehydrogenases of respiratory chains from bacteria (NDH-1) and eukarya (complex I). Like the NADH-dependent enzymes, the F(420)H(2) dehydrogenase is composed of three subcomplexes. The gene products FpoA, H, J, K, L, M, and N are highly hydrophobic and are homologous to subunits that form the membrane integral module of NDH-1. FpoB, C, D, and I have their counterparts in the amphipathic membrane-associated module of NDH-1. Homologues to the hydrophilic NADH-oxidizing input module are not present in M. mazei Gö1. Instead, the gene product FpoF may be responsible for F(420)H(2) oxidation and may function as the electron input part. Thus, the F(420)H(2) dehydrogenase from M. mazei Gö1 resembles eukaryotic and bacterial proton translocating NADH dehydrogenases in many ways. The enzyme from the methanogenic archaeon functions as a NDH-1/complex I homologue and is equipped with an alternative electron input unit for the oxidation of reduced cofactor F(420) and a modified output module adopted to the reduction of methanophenazine.

Membrane-bound F 420 H 2 -dependent heterodisulfide reduction in Methanococcus voltae

Washed membranes prepared from H2+CO2- or formate-grown cells of Methanococcus voltae catalyzed the oxidation of coenzyme F420H2 and the reduction of the heterodisulfide (CoB-S-S-CoM) of 2-mercaptoethanesulfonate and 7-mercaptoheptanoylthreonine phosphate, which is the terminal electron acceptor of the methanogenic pathway. The reaction followed a 1:1 stoichiometry according to the equation: F420H2 + COB-S-S-CoM --> F420 + CoM-SH + CoB-SH. These findings indicate that the reaction depends on a membrane-bound F420H2-oxidizing enzyme and on the heterodisulfide reductase, which remains partly membrane-bound after cell lysis. To elucidate the nature of the F420H2-oxidizing protein, washed membranes were solubilized with detergent, and the enzyme was purified by sucrose density centrifugation, anion-exchange chromatography, and gel filtration. Several lines of evidence indicate that F420H2 oxidation is catalyzed by a membrane-associated F420-reducing hydrogenase. The purified protein catalyzed the H2-dependent reduction of methyl viologen and F420. The apparent molecular mass and the subunit composition (43, 37, and 27 kDa) are almost identical to those of the F420-reducing hydrogenase that has already been purified from Mc. voltae. Moreover, the N-terminus of the 37-kDa subunit is identical to the amino acid sequence deduced from the fruG gene of the operon encoding the selenium-containing F420-reducing hydrogenase from Mc. voltae. A distinct F420H2 dehydrogenase, which is present in methylotrophic methanogens, was not found in this organism.

Alpha-keto acid chain elongation reactions involved in the biosynthesis of coenzyme B (7-mercaptoheptanoyl threonine phosphate) in methanogenic Archaea.

The biochemistry of the 13 steps involved in the conversion of alpha-ketoglutarate and acetylCoA to alpha-ketosuberate, a precursor to the coenzymes coenzyme B (7-mercapto heptanoylthreonine phosphate) and biotin, has been established in Methanosarcina thermophila. These series of reactions begin with the condensation of alpha-ketoglutarate and acetylCoA to form trans-homoaconitate. The trans-homoaconitate is then hydrated and dehydrated to cis-homoaconitate with (S)-homocitrate serving as an intermediate. Rehydration of the cis-homoaconitate produces (-)-threo-isohomocitrate [(2R,3S)-1-hydroxy-1,2, 4-butanetricarboxylic acid], which undergoes a NADP+-dependent oxidative decarboxylation to produce alpha-ketoadipate. The resulting alpha-ketoadipate then undergoes two consecutive sets of alpha-ketoacid chain elongation reactions to produce alpha-ketosuberate. In each of these sets of reactions, it has been shown that the homologues of cis-homoaconitate, homocitrate, and (-)-threo-isohomocitrate serve as intermediates. The protein product of the Methanococcus jannaschii MJ0503 gene aksA (AksA) was found to catalyze the condensation of alpha-ketoglutarate and acetylCoA to form trans-homoaconitate. This gene product also catalyzed the condensation of alpha-ketoadipate or alpha-ketopimelate with acetylCoA to form, respectively, the (R)-homocitrate homologues of (R)-2-hydroxy-1,2,5-pentanetricarboxylic acid and (R)-2-hydroxy-1,2, 6-hexanetricarboxylic acid. The alpha-ketosuberate resulting from this series of reactions then undergoes a nonoxidative decarboxylation to form 7-oxoheptanoic acid, a precursor to coenzyme B, and an oxidative decarboxylation to form pimelate, the precursor to biotin. Of the 13 intermediates in this pathway, eight have not previously been reported as occurring in biological systems.

Biosynthesis of (7-mercaptoheptanoyl)threonine phosphate.

The biosynthesis of (7-mercaptoheptanoyl)threonine phosphate (HS-HTP) has been studied in the methanogenic bacteria Methanococcus volta and Methanosarcina thermophila. Growth of these cells in medium containing [7,7-2H2]-7-mercaptoheptanoic acid, [3,4,4,4-threonine-2H4]-N-(7-mercaptoheptanoyl)threonine, [7,7-2H2]-N-(7-mercaptoheptanoyl)threonine, or DL-[3,4,4,4-2H4]threonine led to the generation of labeled HS-HTP containing a portion of the molecules with the same number of deuteriums as the precursor molecule. This result indicated that each of these labeled molecules can serve as a precursor for the biosynthesis of HS-HTP. Cell-free extracts of these methanogens were shown to carry out the ATP-dependent phosphorylation of N-(7-mercaptoheptanoyl)threonine to HS-HTP. These observations indicate that the biosynthesis of HS-HTP involves the coupling of mercaptoheptanoic acid with threonine to form (7-mercaptoheptanoyl)threonine, which is then phosphorylated to HS-HTP.

Properties of the two isoenzymes of methyl-coenzyme M reductase in Methanobacterium thermoautotrophicum.

Methyl-coenzyme M reductase (MCR) catalyses the methane-forming step in the energy metabolism of methanogenic Archaea. It brings about the reduction of methyl-coenzyme M (CH3-S-CoM) by 7-mercaptoheptanoylthreonine phosphate (H-S-HTP). Methanobacterium thermoautotrophicum contains two isoenzymes of MCR, designated MCR I and MCR II, which are expressed differentially under different conditions of growth. These two isoenzymes have been separated, purified and their catalytic and spectroscopic properties determined. Initial-velocity measurements of the two-substrate reaction showed that the kinetic mechanism for both isoenzymes involved ternary-complex formation. Double reciprocal plots of initial rates versus the concentration of either one of the two substrates at different constant concentrations of the other substrate were linear and intersected on the abcissa to the left of the 1/v axis. The two purified isoenzymes differed in their Km values for H-S-HTP and for CH3-S-CoM and in Vmax. MCR I displayed a Km for H-S-HTP of 0.1-0.3 mM, a Km for CH3-S-CoM of 0.6-0.8 mM and a Vmax of about 6 mumol.min-1 x mg-1 (most active preparation). MCR II showed a Km for H-S-HTP of 0.4-0.6 mM, a Km for CH3-S-CoM of 1.3-1.5 mM and a Vmax of about 21 mumol.min-1 x mg-1 (most active preparation). The pH optimum of MCR I was 7.0-7.5 and that of MCR II 7.5-8.0. Both isoenzymes exhibited very similar temperature activity optima and EPR properties. The location of MCR I and of MCR II within the cell, determined via immunogold labeling, was found to be essentially identical. The possible basis for the existence of MCR isoenzymes in M. thermoautotrophicum is discussed.

Substrate-analogue-induced changes in the nickel-EPR spectrum of active methyl-coenzyme-M reductase from Methanobacterium thermoautotrophicum.

Methyl-coenzyme-M reductase (MCR) catalyzes the formation of methane from methyl-coenzyme M [2-(methylthio)ethanesulfonate] and 7-mercaptoheptanoylthreonine phosphate in methanogenic archaea. The enzyme contains the nickel porphinoid coenzyme F430 as a prosthetic group. In the active, reduced (red) state, the enzyme displays two characteristic EPR signals, MCR-red1 and MCR-red2, probably derived from Ni(I). In the presence of the substrate methyl-coenzyme M, the rhombic MCR-red2 signal is quantitatively converted to the axial MCR-red1 signal. We report here on the effects of inhibitory substrate analogues on the EPR spectrum of the enzyme. 3-Bromopropanesulfonate (BrPrSO3), which is the most potent inhibitor of MCR known to date (apparent Ki = 0.05 microM), converted the EPR signals MCR-red1 and MCR-red2 to a novel axial Ni(I) signal designated MCR-BrPrSO3. 3-Fluoropropanesulfonate (apparent Ki < 50 microM) and 3-iodopropanesulfonate (apparent Ki < 1 microM) induced a signal identical to that induced by BrPrSO3 without affecting the line shape, despite the fact that the fluorine, bromine and iodine isotopes employed have nuclear spins of I = 1/2, I = 3/2 and I = 5/2, respectively. This finding suggests that MCR-BrPrSO3 is not the result of a close halogen-Ni(I) interaction. 7-Bromoheptanoylthreonine phosphate (BrHpoThrP) (apparent Ki = 5 microM), which is an inhibitory substrate analogue of 7-mercaptoheptanoylthreonine phosphate, converted the signals MCR-red1 and MCR-red2 to a novel axial Ni(I) signal, MCR-BrHpoThrP, similar but not identical to MCR-BrPrSO3. The results indicate that inhibition of MCR by the halogenated substrate analogues investigated above is not via oxidation of Ni(I)F430. The different MCR EPR signals are assigned to different enzyme/substrate and enzyme/inhibitor complexes.

Methyl-coenzyme M reductase of Methanobacterium thermoautotrophicum delta H catalyzes the reductive dechlorination of 1,2-dichloroethane to ethylene and chloroethane.

Reductive dechlorination of 1,2-dichloroethane (1,2-DCA) to ethylene and chloroethane (CA) by crude cell extracts of Methanobacterium thermoautotrophicum delta H with H2 as the electron donor was stimulated by Mg-ATP. The heterodisulfide of coenzyme M (CoM) and 7-mercaptoheptanoylthreonine phosphate together with Mg-ATP partially inhibited ethylene production but stimulated CA production compared Mg-ATP alone. The pH optimum for the dechlorination was 6.8 (at 60 degrees C). Michaelis-Menten kinetics for initial product formation rates with different 1,2-DCA concentrations indicated the enzymatic character of the dechlorination. Apparent Kms for 1,2-DCA of 89 and 119 microM and Vmaxs of 34 and 20 pmol/min/mg of protein were estimated for ethylene and CA production, respectively. 3-Bromopropanesulfonate, a specific inhibitor for methyl-CoM reductase, completely inhibited dechlorination of 1,2-DCA. Purified methyl-CoM reductase, together with flavin adenine dinucleotide and a crude component A fraction which reduced the nickel of factor F430 in methyl-CoM reductase, converted 1,2-DCA to ethylene and CA with H2 as the electron donor. In this system, methyl-CoM reductase was also able to transform its own inhibitor 2-bromoethanesulfonate to ethylene.

Characterization of cytochromes from Methanosarcina strain Göl and their involvement in electron transport during growth on methanol.

Methanosarcina strain Gö1 was tested for the presence of cytochromes. Low-temperature spectroscopy, hemochrome derivative spectroscopy, and redox titration revealed the presence of two b-type (b559 and b564) and two c-type (c547 and c552) cytochromes in membranes from Methanosarcina strain Gö1. The midpoint potentials determined were Em,7 = -135 +/- 5 and -240 +/- 11 mV (b-type cytochromes) and Em,7 = -140 +/- 10 and -230 +/- 10 mV (c-type cytochromes). The protoheme IX and the heme c contents were 0.21 to 0.24 and 0.09 to 0.28 mumol/g of membrane protein, respectively. No cytochromes were detectable in the cytoplasmic fraction. Of various electron donors and acceptors tested, only the reduced form of coenzyme F420 (coenzyme F420H2) and the heterodisulfide of coenzyme M and 7-mercaptoheptanoylthreonine phosphate (CoM-S-S-HTP) were capable of reducing and oxidizing the cytochromes at a high rate, respectively. Addition of CoM-S-S-HTP to reduced cytochromes and subsequent low-temperature spectroscopy revealed the oxidation of cytochrome b564. On the basis of these results, we suggest that one or several cytochromes participate in the coenzyme F420H2-dependent reduction of the heterodisulfide.

7-Mercaptoheptanoylthreonine phosphate substitutes for heat-stable factor (mobile factor) for growth of Methanomicrobium mobile

Methanomicrobium mobile requires a heat-stable factor present in ruminal fluid and in boiled cell extract from Methanobacterium thermoautotrophicum for growth. By comparing the growth of M. mobile with boiled cell extract with that observed with various methanogenic cofactors, we found that 7-mercaptoheptanoylthreonine phosphate (HS-HTP) supported sustained growth of M. mobile, at an optimal concentration of 100 microM. No derivatives or possible biosynthetic precursors of HS-HTP could replace HS-HTP as the sole source of growth factor. Results suggest that the growth requirement might be satisfied by 7-mercaptoheptanoic acid plus a second, unidentified heat-stable factor.

Purification and properties of methyl coenzyme M methylreductase from acetate-grown Methanosarcina thermophila

Methyl coenzyme M methylreductase from acetate-grown Methanosarcina thermophila TM-1 was purified 16-fold from a cell extract to apparent homogeneity as determined by native polyacrylamide gel electrophoresis. Ninety-four percent of the methylreductase activity was recovered in the soluble fraction of cell extracts. The estimated native molecular weight of the enzyme was between 132,000 (standard deviation [SD], 1,200) and 141,000 (SD, 1,200). Denaturing polyacrylamide gel electrophoresis revealed three protein bands corresponding to molecular weights of 69,000 (SD, 1,200), 42,000 (SD, 1,200), and 33,000 (SD, 1,200) and indicated a subunit configuration of alpha 1 beta 1 gamma 1. As isolated, the enzyme was inactive but could be reductively reactivated with titanium (III) citrate or reduced ferredoxin. ATP stimulated enzyme reactivation and was postulated to be involved in a conformational change of the inactive enzyme from an unready state to a ready state that could be reductively reactivated. The temperature and pH optima for enzyme activity were 60 degrees C and between 6.5 and 7.0, respectively. The active enzyme contained 1 mol of coenzyme F430 per mol of enzyme (Mr, 144,000). The Kms for 2-(methylthio)ethane-sulfonate and 7-mercaptoheptanoylthreonine phosphate were 3.3 mM and 59 microM, respectively.

H2: heterodisulfide oxidoreductase, a second energy-conserving system in the methanogenic strain G�1

Washed everted vesicles of the methanogenic bacterium strain Go1 catalyzed an H2-dependent reduction of the heterodisulfide of HS-CoM (2-mercaptoethanesulfonate) and HS-HTP (7-mercaptoheptanoylthreonine phosphate) (CoM-S-S-HTP). This process was independent of coenzyme F420 and was coupled to proton translocation across the cytoplasmic membrane into the lumen of the everted vesicles. The maximal H+/CoM-S-S-HTP ratio was 2. The tranmembrane electrochemical gradient thereby generated was shown to induce ATP synthesis from ADP+Pi, exhibiting a stoichiometry of 1 ATP synthesized per 2 CoM-S-S-HTP reduced (H+/ATP=4). ATP formation was inhibited by the uncoupler 3,5-di-tert-butyl-4-hydroxy-benzylidene-malononitrile (SF 6847) and by the ATP synthase inhibitor N,N′-dicyclohexylcarbodiimide (DCCD). This energy-conserving system showed a stringent coupling. The addition of HS-CoM and HS-HTP at 1 mM each decreased the heterodisulfide reductase activity to 50% of the control. Membranes from Methanolobus tindarius showed F420H2-dependent but no H2-dependent heterodisulfide oxidoreductase activity. Neither of these activities was detectable in membranes of Methanococcus thermolithotrophicus.

Reduced coenzyme F420: heterodisulfide oxidoreductase, a proton- translocating redox system in methanogenic bacteria.

Washed everted vesicles of the methanogenic bacterium strain Go1 were found to couple the F420H2-dependent heterodisulfide reduction with the transfer of protons across the membrane into the lumen of the everted vesicles. The transmembrane electrochemical potential of protons thereby generated was shown to be competent in driving ATP synthesis from ADP + Pi, exhibiting a stoichiometry of 2 H+ translocated or 0.4 ATP synthesized per F420H2 oxidized. This enzyme system exhibits the phenomenon of coupling and uncoupling and represents a different kind of electron transport chain with the heterodisulfide of 2-mercaptoethanesulfonate and 7-mercaptoheptanoylthreonine phosphate as terminal electron acceptor. The heterodisulfide and methane are formed in the methyl coenzyme M reductase reaction. The reducing equivalents are derived from reduced coenzyme F420, which represents an analogue of NADH + H+ in other respiratory chains. It is assumed that the proton-translocating oxidoreductase discovered in strain Go1 is of principal importance to all methanogenic bacteria not utilizing H2.

Stimulation of the methyltetrahydromethanopterin: coenzyme M methyltransferase reaction in cell-free extracts of Methanobacterium thermoautotrophicum by the heterodisulfide of coenzyme M and 7-mercaptoheptanoylthreonine phosphate

The conversion of formaldehyde to methylcoenzyme M in cell-free extracts of Methanobacterium thermoautotrophicum was stimulated up to 10-fold by catalytic amounts of the heterodisulfide (CoM-S-S-HTP) of coenzyme M and 7-mercaptoheptanoylthreonine phosphate. The stimulation required the additional presence of ATP, also in catalytic concentrations. ATP and CoM-S-S-HTP were mutually stimulatory on the methylcoenzyme M formation and it was concluded that the compounds were both involved in the reductive activation of the methyltetrahydromethanopterin: coenzyme M methyltransferase. Micromolar concentrations of benzyl viologen or cyanocobalamin inhibited the formaldehyde conversion; these compounds, however, strongly stimulated the reduction of CoM-S-S-HTP. The results described here closely resemble observations made on the activation and reduction of CO2 to formylmethanofuran indicating that this step and the reductive activation of the methyltransferase are controlled by some common mechanism.

ATP synthesis coupled to electron transfer from H 2 to the heterodisulfide of 2-mercaptoethanesulfonate and 7-mercaptoheptanoylthreonine phosphate in vesicle preparations of the methanogenic bacterium strain Gö1

Crude vesicle preparations of the methanogenic strain Gol were able to couple the reduction of the heterodisulfide of 2-mercaptoethanesulfonate and 7-mercaptoheptanoylthreonine phosphate (CoM- S- S-HTP) by H 2 with ATP formation. The rate of ATP synthesis was 1 nmol min mg protein. ATP synthesis and disulfide reduction were only observed with CoM- S- S-HTP, but not with CoM- S- S-CoM or HTP- S- S-HTP. The methylreductase inhibitor 2-bromoethanesulfonic acid had no effect on ATP synthesis induced by CoM- S- S-HTP reduction with H 2. ATP synthesis was completely inhibited by the uncoupler SF 6847 whereas the concomitant CoM- S- S-HTP reduction was stimulated. The ATP synthase inhibitors DCCD and DES also inhibited ATP formation completely and decreased the CoM- S- S-HTP reduction rate to 35% of the control. These inhibitory effects were abolished by addition of the uncoupler. From these results it is concluded that energy coupling between the electron transfer from H 2 to the heterodisulfide and ATP synthesis occurs via a transmembrane proton gradient.

Membrane-bound F 420H 2-dependent heterodisulfide reductase in methanogenic bacterium strain Göl and Methanolobus tindarius

Washed membrane or cytoplasmic fractions of the methanogenic bacterium strain Göl catalyzed the oxidation of coenzyme F 420H 2 with a variety of electron acceptors. The F 420H 2-oxidizing activity of the cytoplasmic fraction could be assigned to a NADP +:F 420 oxidoreductase. The membrane fraction but not the cytoplasmic fraction catalyzed the oxidation of F 420H 2 with the concomitant reduction of the heterodisulfide of 2-mercapto-ethanesulfonate and 7-mercaptoheptanoylthreonine phosphate (CoM-S-S-HTP) at a rate of 100 nmol min-mg protein according to the following equation: F 420H 2+CoM-S-S-HTP → F 420 + CoM + HTP-SH. The activity depended linearly on the membrane protein up to a concentration of 60 μg ml The physiological electron acceptor CoM-S-S-HTP could not be replaced by the corresponding homodisulfides CoM-S-S-CoM and HTP-S-S-HTP or by NADP +. A membrane-bound F 420H 2-dependent CoM-S-S-HTP reductase was also detected in Methanolobus tindarius exhibiting a specific activity of 75 nmol min m ̇ g protein. The absence of a F 420-dependent hydrogenase in this organism excludes the involvement of this enzyme in electron transfer from H 420H 2 to CoM-S-S-HTP.

Catalytic properties of the heterodisulfide reductase involved in the final step of methanogenesis

Reduction of the heterodisulfide of coenzyme M (H-S-CoM) and 7-mercaptoheptanoyl(L)threonine phosphate (H-S-HTP) is a partial reaction in methanogenesis. The CoM-S-S-HTP reductase mediating this reaction has thus far not been studied. We report here that the enzyme from Methanobacterium thermoautotrophicum and Methanosarcina barkeri catalyzes the reduction of CoM-S-S-HTP with reduced viologen dyes and, in the reverse direction, the oxidation of H-S-CoM plus H-S-HTP to the heterodisulfide by methylene blue. The CoM-S-S-HTP reductase from M. thermoautotrophicum (strain Marburg) was partially purified (30-fold) to a specific activity of 10 μmol·min −1·mg protein −1. The enzyme was highly substrate specific: e.g. neither the heterodisulfide derived from 6-mercaptohexanoylthreonine phosphate nor the homodisulfide of H-SCoM or of HSHTP was reduced. The D-enantiomer of CoM-S-S-HTP was, however, converted at 35% of the specific rate of the L-form. Apparent K m and apparent V max values for substrates and products were determined.

Methyl‐coenzyme‐M reductase from Methanobacterium thermoautotrophicum (strain Marburg)

Methyl-coenzyme-M reductase from Methanobacterium thermoautotrophicum (strain Marburg) was purified to a stage where, besides the alpha, beta and gamma subunits, no additional polypeptides were detectable in the preparation. Under appropriate conditions the enzyme was found to catalyze the reduction of methyl-CoM with 7-mercaptoheptanoylthreonine phosphate (H-S-HTP) to CH4 at a specific rate of 2.5 mumol.min-1.mg protein-1. This finding contradicts a recent report that methyl-CoM reductase is only active when some contaminating proteins are present. The two polypeptides encoded by the open reading frames ORF1 and ORF2 of the methyl-CoM reductase transcription unit did not co-purify with the alpha, beta and gamma subunits. They were neither required nor did they stimulate the activity under the assay conditions. 3-Bromopropanesulfonate (apparent Ki = 0.05 microM) and 2-azidoethanesulfonate (apparent Ki = 1 microM) were found to be two new competitive inhibitors of methyl-CoM reductase. Both inhibitors were considerably more effective than the "classical" 2-bromoethanesulfonate (apparent Ki = 4 microM).