Simonida Gencic scite author profile

The methanogenic Archaea utilize a unique metabolic pathway for degradation of acetate under anaerobic conditions, and cleavage of acetate thereby accounts for a major proportion of the methane formed in the environment. The central reaction in this pathway is carried out by an unusual multienzyme complex, designated acetyl-CoA decarbonylase/synthase (ACDS), 1 which contains five different polypeptide subunits and accounts for as much as 25% of the soluble protein in species such as Methanosarcina thermophila and Methanosarcina barkeri growing on acetate. The ACDS complex catalyzes cleavage of the acetyl C-C bond using the substrates acetylCoA and tetrahydrosarcinapterin (H 4 SPt), a tetrahydrofolate analog which serves as methyl acceptor, and yields the products CoA, N 5 -methyltetrahydrosarcinapterin, CO 2 , and two reducing equivalents, as given in Reaction 1 (1).This overall reaction is made up of a series of partial reactions catalyzed by different protein subcomponents of the ACDS complex as shown in Scheme 1 (2). Acetyl-CoA binds to the ␤ subunit, and under low redox potential conditions, as required for activity, transfers the acetyl group to a nucleophilic center on the enzyme forming an acetyl-enzyme species and releasing CoA (Scheme 1, acetyl transfer) (2, 3). The acetyl intermediate then undergoes C-C bond cleavage by a reaction that is presumed to involve metal-based decarbonylation and/or methyl group migration (Scheme 1, cleavage). The nascent methyl group is then transferred to a corrinoid cofactor present on the ␥␦ subcomponent, which catalyzes subsequent methyl transfer to the substrate H 4 SPt (Scheme 1, methyl transfer) (2). The carbonyl group is oxidized to CO 2 by a process involving the ␣⑀ CO dehydrogenase subcomponent, with regeneration of the reduced form of the ␤ subunit. Previous studies on the ␤ subunit have focused on a C-terminally truncated form of the protein purified from the native ACDS complex following partial proteolytic digestion (2-4).The genes encoding the five ACDS subunits are arranged together in an operon along with one additional open reading frame in all species of Methanosarcina and in certain other methanogens as well (5-7, 9).2 The operon structure is shown in Scheme 2, with the designated genes and corresponding subunit molecular masses indicated for M. thermophila TM-1. The additional open reading frame encodes an accessory protein thought to be involved in nickel insertion, and nickel is present in both the large CO dehydrogenase subunit ␣ (CdhA) and in the ␤ subunit (CdhC) containing the active site for

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Mutation of the proteolipid protein gene PLP in a human X chromosome-linked myelin disorder.

Hudson

Puckett

Berndt

et al. 1989

Proc. Natl. Acad. Sci. U.S.A.

182

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The A-Cluster in Subunit β of the Acetyl-CoA Decarbonylase/Synthase Complex from Methanosarcina thermophila: Ni and Fe K-Edge XANES and EXAFS Analyses

Gencic

Cramer

et al. 2003

J. Am. Chem. Soc.

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The acetyl-CoA decarbonylase/synthase (ACDS) complex catalyzes the cleavage of acetyl-CoA in methanogens that metabolize acetate to CO(2) and CH(4), and also carries out acetyl-CoA synthesis during growth on one-carbon substrates. The ACDS complex contains five subunits, among which beta possesses an Ni-Fe-S active-site metal cluster, the A-cluster, at which reaction with acetyl-CoA takes place, generating an acetyl-enzyme species poised for C-C bond cleavage. We have used Ni and Fe K fluorescence XANES and EXAFS analyses to characterize these metals in the ACDS beta subunit, expressed as a C-terminally shortened form. Fe XANES and EXAFS confirmed the presence of an [Fe(4)S(4)] cluster, with typical Fe-S and Fe-Fe distances of 2.3 and 2.7 A respectively. An Fe:Ni ratio of approximately 2:1 was found by Kalphabeta fluorescence analysis, indicating 2 Ni per [Fe(4)S(4)]. Ni XANES simulations were consistent with two distinct Ni sites in cluster A, and the observed spectrum could be modeled as the sum of separate square planar and tetrahedral Ni sites. Treatment of the beta subunit with Ti(3+) citrate resulted in shifts to lower energy, implying significant reduction of the [Fe(4)S(4)] center, along with conversion of a smaller fraction of Ni(II) to Ni(I). Reaction with CO in the presence of Ti(3+) citrate generated a unique Ni XANES spectrum, while effects on the Fe-edge were not very different from the reaction with Ti(3+) alone. Ni EXAFS revealed an average Ni coordination of 2.5 S at 2.19 A and 1.5 N/O at 1.89 A. A distinct feature at approximately 2.95 A most likely results from Ni-Ni interaction. The methanogen beta subunit A-cluster is proposed to consist of an [Fe(4)S(4)] cluster bridged to an Ni-Ni center with one Ni in square planar geometry coordinated by 2 S + 2 N and the other approximately tetrahedral with 3 S + 1 N/O ligands. The electronic consequences of two distinct Ni geometries are discussed.

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Two Separate One-Electron Steps in the Reductive Activation of the A Cluster in Subunit β of the ACDS Complex in Methanosarcina thermophila

Gencic

Grahame

2008

Biochemistry

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Acetyl-CoA decarbonylase/synthase (ACDS) is a multienzyme complex found in methanogens and certain other Archaea that carries out the overall synthesis and cleavage of the acetyl C-C and C-S bonds of acetyl-CoA. The reaction is involved both in the autotrophic fixation of carbon and in the process of methanogenesis from acetate, and takes place at a unique active site metal center known as the A cluster, located on the beta subunit of the ACDS complex and composed of a binuclear Ni-Ni site bridged by a cysteine thiolate to an Fe4S4 center. In this work, a high rate of acetyl-CoA synthesis was achieved with the recombinant ACDS beta subunit by use of methylcobinamide as an appropriate mimic of the physiological base-off corrinoid substrate. The redox dependence of acetyl-CoA synthesis exhibited one-electron Nernst behavior, and the effects of pH on the observed midpoint potential indicated that reductive activation of the A cluster also involves protonation. Initial burst kinetic studies indicated the formation of stoichiometric amounts of an A cluster-acetyl adduct, further supported by direct chromatographic isolation of an active enzyme-acetyl species. Titration experiments indicated that two electrons are required for activation of the enzyme in the process of forming the enzyme-acetyl intermediate. The results also established that the A cluster-acetyl species undergoes reductive elimination of the acetyl group with the simultaneous release of two, low potential electron equivalents. Thus, the one-electron Nernst behavior can be interpreted as the sum of two separate, low potential, one-electron steps. The results tend to exclude reaction mechanisms involving either one- or three-electron reduced forms of the A cluster as immediate precursors to the acetyl species. A scheme involving a [Fe4S4]1+-Ni1+ species is favored over a [Fe4S4]2+-Ni0 form. The role of proton uptake in the possible formation of a Ni2+-hydride intermediate is also discussed. Trapping of electrons during the formation of the A cluster-acetyl species from substrates CO and methylcobinamide was found to be highly favorable, thus presenting a means for extensive activation of the enzyme under otherwise nonpermissive physiological redox potentials.

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Zinc−Thiolate Intermediate in Catalysis of Methyl Group Transfer in Methanosarcina barkeri

et al. 2001

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Methyl group transfer reactions are essential in methane-forming pathways in all methanogens. The involvement of zinc in catalysis of methyl group transfer was studied for the methyltransferase enzyme MT2-A important for methanogenesis in Methanosarcina barkeri growing on methylamines. Zinc was shown to be required for MT2-A activity and was tightly bound by the enzyme with an apparent stability constant of 10(13.7) at pH 7.2. Oxidation was a factor influencing activity and metal stoichiometry of purified MT2-A preparations. Methods were developed to produce inactive apo MT2-A and to restore full activity with stoichiometric reincorporation of Zn(2+). Reconstitution with Co(2+) yielded an enzyme with 16-fold higher specific activity. Cysteine thiolate coordination in Co(2+)-MT2-A was indicated by high absorptivity in the 300-400 nm charge transfer region, consistent with more than one thiolate ligand at the metal center. Approximate tetrahedral geometry was indicated by strong d-d transition absorbance centered at 622 nm. EXAFS analyses of Zn(2+)-MT2-A revealed 2S + 2N/O coordination with evidence for involvement of histidine. Interaction with the substrate CoM (2-mercaptoethanesulfonic acid) resulted in replacement of the second N/O group with S, indicating direct coordination of the CoM thiolate. UV-visible spectroscopy of Co(2+)-MT2-A in the presence of CoM also showed formation of an additional metal-thiolate bond. Binding of CoM over the range of pH 6.2-7.7 obeyed a model in which metal-thiolate formation occurs separately from H(+) release from the enzyme-substrate complex. Proton release to the solvent takes place from a group with apparent pK(a) of 6.4, and no evidence for metal-thiolate protonation was found. It was determined that substrate metal-thiolate bond formation occurs with a Delta G degrees ' of -6.7 kcal/mol and is a major thermodynamic driving force in the overall process of methyl group transfer.

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Simonida Gencic

Nickel in Subunit β of the Acetyl-CoA Decarbonylase/Synthase Multienzyme Complex in Methanogens

Mutation of the proteolipid protein gene PLP in a human X chromosome-linked myelin disorder.

The A-Cluster in Subunit β of the Acetyl-CoA Decarbonylase/Synthase Complex from Methanosarcina thermophila: Ni and Fe K-Edge XANES and EXAFS Analyses

Two Separate One-Electron Steps in the Reductive Activation of the A Cluster in Subunit β of the ACDS Complex in Methanosarcina thermophila

Zinc−Thiolate Intermediate in Catalysis of Methyl Group Transfer in Methanosarcina barkeri

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