Sequence and transcript analysis of a novel Methanosarcina barkeri methyltransferase II homolog and its associated corrinoid protein homologous to methionine synthase

Paul, Ligi; Krzycki, Joseph A.

doi:10.1128/jb.178.22.6599-6607.1996

Cited by 46 publications

(64 citation statements)

References 59 publications

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“…MtsB is highly similar to the entire length of methylotrophic corrinoid proteins such as MttC, MtbC, or MtmC (30,33). These latter proteins bind one corrinoid cofactor per polypeptide (21,26,27,35).…”

Section: Discussionmentioning

confidence: 91%

“…MtsA shares ϳ50% similarity over nearly its entire length to the CoM methylases involved in CoM methylation by methanol (MtaA) and methylamine (MtbA) (33), and, as one would predict, they share some similarities. Like MtaA and MtbA, MtsA catalyzes an active methylcobalamin:CoM methyl transfer reaction.…”

Section: Discussionmentioning

confidence: 99%

“…Like MtaA and MtbA, MtsA catalyzes an active methylcobalamin:CoM methyl transfer reaction. The sequence of all three proteins (32,33) possess the proposed binding motif (V/I)LHICG, where zinc may coordinate to the His and Cys residues, as well as to a second Cys residue found 75 residues C-terminal to the first Cys residue (32,46). MtsA, like MtbA and MtaA, binds 1 mol of zinc/mol of polypeptide.…”

Section: Discussionmentioning

confidence: 99%

“…The methylamine cognate corrinoid proteins each bind one corrinoid per polypeptide (21,26,35), and these proteins as a group are homologous to the cobalamin binding domains of methionine synthase, as well as coenzyme B 12 -dependent enzymes (30,33,36). MtsB contains all expected signature residues for binding corrinoid (33,37) and is therefore the likely corrinoid binding subunit of methylthiol: CoM methyltransferase. Thus, a clear route for the demethylation of methylated MtsB corrinoid protein and methylation of CoM can be proposed, in that MtsA mediates the demethylation of MtsB and methylation of CoM (Fig.…”

mentioning

confidence: 99%

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The MtsA Subunit of the Methylthiol:Coenzyme M Methyltransferase of Methanosarcina barkeri Catalyses Both Half-reactions of Corrinoid-dependent Dimethylsulfide: Coenzyme M Methyl Transfer

Tallant

Paul²,

Krzycki

2001

Journal of Biological Chemistry

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Section: Discussionmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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The MtsA Subunit of the Methylthiol:Coenzyme M Methyltransferase of Methanosarcina barkeri Catalyses Both Half-reactions of Corrinoid-dependent Dimethylsulfide: Coenzyme M Methyl Transfer

Tallant

Paul²,

Krzycki

2001

Journal of Biological Chemistry

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“…were found, but these were not near corrinoid proteins or their associated methyltransferases. An exception was a gene encoding a Ram-like homolog found in M. barkeri Fusaro (Mbar_A3583) near the genes most similar to the methylthiol:CoM methyltransferase, a corrinoid-dependent methyltransferase homologous to methylamine corrinoid proteins and methylcobamide:CoM methyltransferases (47,48). A RamA homolog (MA0849) was also found in M. acetivorans adjacent to a gene encoding a methylcobamide:CoM methyltransferase homolog.…”

Section: Rama Is Encoded By a Gene With A C-terminal Ferredoxinlike Dmentioning

confidence: 99%

RamA, a Protein Required for Reductive Activation of Corrinoid-dependent Methylamine Methyltransferase Reactions in Methanogenic Archaea

Ferguson

Soares

Lienard

et al. 2009

Journal of Biological Chemistry

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Archaeal methane formation from methylamines is initiated by distinct methyltransferases with specificity for monomethylamine, dimethylamine, or trimethylamine. Each methylamine methyltransferase methylates a cognate corrinoid protein, which is subsequently demethylated by a second methyltransferase to form methyl-coenzyme M, the direct methane precursor. Methylation of the corrinoid protein requires reduction of the central cobalt to the highly reducing and nucleophilic Co(I) state. RamA, a 60-kDa monomeric ironsulfur protein, was isolated from Methanosarcina barkeri and is required for in vitro ATP-dependent reductive activation of methylamine:CoM methyl transfer from all three methylamines. In the absence of the methyltransferases, highly purified RamA was shown to mediate the ATP-dependent reductive activation of Co(II) corrinoid to the Co(I) state for the monomethylamine corrinoid protein, MtmC. The ramA gene is located near a cluster of genes required for monomethylamine methyltransferase activity, including MtbA, the methylamine-specific CoM methylase and the pyl operon required for co-translational insertion of pyrrolysine into the active site of methylamine methyltransferases. RamA possesses a C-terminal ferredoxinlike domain capable of binding two tetranuclear iron-sulfur proteins. Mutliple ramA homologs were identified in genomes of methanogenic Archaea, often encoded near methyltrophic methyltransferase genes. RamA homologs are also encoded in a diverse selection of bacterial genomes, often located near genes for corrinoid-dependent methyltransferases. These results suggest that RamA mediates reductive activation of corrinoid proteins and that it is the first functional archetype of COG3894, a family of redox proteins of unknown function.

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Cobalamin‐Dependent and Cobalamin‐Independent Methionine Synthases: Are There Two Solutions to the Same Chemical Problem?

Matthews

Smith

Zhou

et al. 2003

Helvetica Chimica Acta

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Dedicated to Professor Duilio Arigoni on the occasion of his 75th birthday.−I find the reaction catalyzed by cobalamin-dependent methionine synthase improbable and that catalyzed by cobalamin-independent methionine synthase impossible.× Duilio Arigoni to Rowena Matthews, Z¸rich, 1989 Two enzymes in Escherichia coli, cobalamin-independent methionine synthase (MetE) and cobalamindependent methionine synthase (MetH), catalyze the conversion of homocysteine (Hcy) to methionine using N(5)-methyltetrahydrofolate (CH 3 -H 4 folate) as the Me donor. Despite the absence of sequence homology, these enzymes employ very similar catalytic strategies. In each case, the pK a for the SH group of Hcy is lowered by coordination to Zn 2 , which increases the concentration of the reactive thiolate at neutral pH. In each case, activation of CH 3 -H 4 folate appears to involve protonation at N(5). CH 3 -H 4 folate remains unprotonated in binary E ¥ CH 3 -H 4 folate complexes, and protonation occurs only in the ternary E ¥ CH 3 -H 4 folate ¥ Hcy complex in MetE, or in the ternary E ¥ CH 3 -H 4 folate ¥ cob(I)alamin complex in MetH. Surprisingly, the similarities are proposed to extend to the structures of these two unrelated enzymes. The structure of a homologue of the Hcybinding region of MetH, betaineÀhomocysteine methyltransferase, has been determined. A search of the threedimensional-structure data base by means of the structure-comparison program DALI indicates similarity of the BHMT structure with that of uroporphyrin decarboxylase (UroD), a homologue of the MT2-A and MT2-M proteins from Archaea, which catalyze Me transfers from methylcorrinoids to coenzyme M and share the Znbinding scaffold of MetE. Here, we present a model for the Zn binding site of MetE, obtained by grafting the Zn ligands of MT2-A onto the structure of UroD.

show abstract

Sequence and transcript analysis of a novel Methanosarcina barkeri methyltransferase II homolog and its associated corrinoid protein homologous to methionine synthase

Cited by 46 publications

References 59 publications

The MtsA Subunit of the Methylthiol:Coenzyme M Methyltransferase of Methanosarcina barkeri Catalyses Both Half-reactions of Corrinoid-dependent Dimethylsulfide: Coenzyme M Methyl Transfer

The MtsA Subunit of the Methylthiol:Coenzyme M Methyltransferase of Methanosarcina barkeri Catalyses Both Half-reactions of Corrinoid-dependent Dimethylsulfide: Coenzyme M Methyl Transfer

RamA, a Protein Required for Reductive Activation of Corrinoid-dependent Methylamine Methyltransferase Reactions in Methanogenic Archaea

Cobalamin‐Dependent and Cobalamin‐Independent Methionine Synthases: Are There Two Solutions to the Same Chemical Problem?

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