Insights into pyrrolysine function from structures of a trimethylamine methyltransferase and its corrinoid protein complex.

The 22nd genetically encoded amino acid, pyrrolysine, plays a unique role in the key step in the growth of methanogens on mono-, di-, and tri-methylamines by activating the methyl group of these substrates for transfer to a corrinoid cofactor. Previous crystal structures of the Methanosarcina barkeri monomethylamine methyltransferase elucidated the structure of pyrrolysine and provide insight into its role in monomethylamine activation. Herein, we report the second structure of a pyrrolysine-containing protein, the M.

The MttB superfamily member MtyB from the human gut symbiont Eubacterium limosum is a cobalamin-dependent γ-butyrobetaine methyltransferase.

The production of trimethylamine (TMA) from quaternary amines such as l-carnitine or γ-butyrobetaine (4-(trimethylammonio)butanoate) by gut microbial enzymes has been linked to heart disease. This has led to interest in enzymes of the gut microbiome that might ameliorate net TMA production, such as members of the MttB superfamily of proteins, which can demethylate TMA (e.g.

Kinetic and substrate complex characterization of RamA, a corrinoid protein reductive activase from Methanosarcina barkeri.

In microbial corrinoid-dependent methyltransferase systems, adventitious Co(I)-corrinoid oxidation halts catalysis and necessitates repair by ATP-dependent reductive activases. RamA, an activase with a C-terminal ferredoxin domain with two [4Fe-4S] clusters from methanogenic archaea, has been far less studied than the bacterial activases bearing an N-terminal ferredoxin domain with one [2Fe-2S] cluster. These differences suggest RamA might prove to have other distinctive characteristics.

MtcB, a member of the MttB superfamily from the human gut acetogen , is a cobalamin-dependent carnitine demethylase.

The trimethylamine methyltransferase MttB is the first described member of a superfamily comprising thousands of microbial proteins. Most members of the MttB superfamily are encoded by genes that lack the codon for pyrrolysine characteristic of trimethylamine methyltransferases, raising questions about the activities of these proteins. The superfamily member MtcB is found in the human intestinal isolate ATCC 8486, an acetogen that can grow by demethylation of l-carnitine.

MtpB, a member of the MttB superfamily from the human intestinal acetogen , catalyzes proline betaine demethylation.

The trimethylamine methyltransferase MttB is the founding member of a widely distributed superfamily of microbial proteins. Genes encoding most members of the MttB superfamily lack the codon for pyrrolysine that distinguishes previously characterized trimethylamine methyltransferases, leaving the function(s) of most of the enzymes in this superfamily unknown. Here, investigating the MttB family member MtpB from the human intestinal isolate ATCC 8486, an acetogen that excretes methyl proline during growth on proline betaine, we demonstrate that MtpB catalyzes anoxic demethylation of proline betaine.

Microbial metabolisms in a 2.5-km-deep ecosystem created by hydraulic fracturing in shales.

Hydraulic fracturing is the industry standard for extracting hydrocarbons from shale formations. Attention has been paid to the economic benefits and environmental impacts of this process, yet the biogeochemical changes induced in the deep subsurface are poorly understood. Recent single-gene investigations revealed that halotolerant microbial communities were enriched after hydraulic fracturing.

A nonpyrrolysine member of the widely distributed trimethylamine methyltransferase family is a glycine betaine methyltransferase.

COG5598 comprises a large number of proteins related to MttB, the trimethylamine:corrinoid methyltransferase. MttB has a genetically encoded pyrrolysine residue proposed essential for catalysis. MttB is the only known trimethylamine methyltransferase, yet the great majority of members of COG5598 lack pyrrolysine, leaving the activity of these proteins an open question.

The path of lysine to pyrrolysine.

Pyrrolysine is the 22nd genetically encoded amino acid. For many years, its biosynthesis has been primarily a matter for conjecture. Recently, a pathway for the synthesis of pyrrolysine from two molecules of lysine was outlined in which a radical SAM enzyme acts as a lysine mutase to generate a methylated ornithine from lysine, which is then ligated to form an amide with the ɛ-amine of a second lysine.

PylSn and the homologous N-terminal domain of pyrrolysyl-tRNA synthetase bind the tRNA that is essential for the genetic encoding of pyrrolysine.

Pyrrolysine is represented by an amber codon in genes encoding proteins such as the methylamine methyltransferases present in some Archaea and Bacteria. Pyrrolysyl-tRNA synthetase (PylRS) attaches pyrrolysine to the amber-suppressing tRNA(Pyl). Archaeal PylRS, encoded by pylS, has a catalytic C-terminal domain but an N-terminal region of unknown function and structure.

Functional context, biosynthesis, and genetic encoding of pyrrolysine.

In Methanosarcina spp., amber codons in methylamine methyltransferase genes are translated as the 22nd amino acid, pyrrolysine. The responsible pyl genes plus amber-codon containing methyltransferase genes have been identified in four archaeal and five bacterial genera, including one human pathogen.

The complete biosynthesis of the genetically encoded amino acid pyrrolysine from lysine.

Pyrrolysine, the twenty-second amino acid found to be encoded in the natural genetic code, is necessary for all of the known pathways by which methane is formed from methylamines. Pyrrolysine comprises a methylated pyrroline carboxylate in amide linkage to the ε-amino group of L-lysine. In certain Archaea, three methyltransferases initiate methanogenesis from the various methylamines, and these enzymes are encoded by genes with an in-frame amber codon that is translated as pyrrolysine.

Assay of methylotrophic methyltransferases from methanogenic archaea.

The family Methanosarcinaceae has an expanded repertoire of growth substrates relative to most other methanogenic archaea. Various methylamines, methylated thiols, and methanol can serve as precursors to both methane and carbon dioxide. These compounds are mobilized into metabolism by methyltransferases that use the growth substrate to methylate a cognate corrinoid protein, which in turn is used as a substrate by a second methyltransferase to methylate Coenzyme M (CoM), forming methyl-SCoM, the precursor to both methane and carbon dioxide.

Selenocysteine, pyrrolysine, and the unique energy metabolism of methanogenic archaea.

Methanogenic archaea are a group of strictly anaerobic microorganisms characterized by their strict dependence on the process of methanogenesis for energy conservation. Among the archaea, they are also the only known group synthesizing proteins containing selenocysteine or pyrrolysine. All but one of the known archaeal pyrrolysine-containing and all but two of the confirmed archaeal selenocysteine-containing protein are involved in methanogenesis.

Specificity of pyrrolysyl-tRNA synthetase for pyrrolysine and pyrrolysine analogs.

Pyrrolysine, the 22nd amino acid, is encoded by amber (TAG=UAG) codons in certain methanogenic archaea and bacteria. PylS, the pyrrolysyl-tRNA synthetase, ligates pyrrolysine to tRNA(Pyl) for amber decoding as pyrrolysine. PylS and tRNA(Pyl) have potential utility in making tailored recombinant proteins.

RamA, a protein required for reductive activation of corrinoid-dependent methylamine methyltransferase reactions in methanogenic archaea.

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.

Structure of the alpha2epsilon2 Ni-dependent CO dehydrogenase component of the Methanosarcina barkeri acetyl-CoA decarbonylase/synthase complex.

Ni-dependent carbon monoxide dehydrogenases (Ni-CODHs) are a diverse family of enzymes that catalyze reversible CO:CO(2) oxidoreductase activity in acetogens, methanogens, and some CO-using bacteria. Crystallography of Ni-CODHs from CO-using bacteria and acetogens has revealed the overall fold of the Ni-CODH core and has suggested structures for the C cluster that mediates CO:CO(2) interconversion. Despite these advances, the mechanism of CO oxidation has remained elusive.

Class I and class II lysyl-tRNA synthetase mutants and the genetic encoding of pyrrolysine in Methanosarcina spp.

Methanosarcina spp. begin methanogenesis from methylamines with methyltransferases made via the translation of UAG as pyrrolysine. In vitro evidence indicates two possible routes to pyrrolysyl-tRNA(Pyl).

A natural genetic code expansion cassette enables transmissible biosynthesis and genetic encoding of pyrrolysine.

Pyrrolysine has entered natural genetic codes by the translation of UAG, a canonical stop codon. UAG translation as pyrrolysine requires the pylT gene product, an amber-decoding tRNA(Pyl) that is aminoacylated with pyrrolysine by the pyrrolysyl-tRNA synthetase produced from the pylS gene. The pylTS genes form a gene cluster with pylBCD, whose functions have not been investigated.

In vivo contextual requirements for UAG translation as pyrrolysine.

Pyrrolysine and selenocysteine have infiltrated natural genetic codes via the translation of canonical stop codons. UGA translation as selenocysteine is absolutely dependent on message context. Here we describe the first experimental examination of contextual requirements for UAG translation as pyrrolysine.

Characterization of a Methanosarcina acetivorans mutant unable to translate UAG as pyrrolysine.

The methyltransferases initiating methanogenesis from trimethylamine, dimethylamine and monomethylamine possess a novel residue, pyrrolysine. Pyrrolysine is the 22nd amino acid, because it is encoded by a single amber (UAG) codon in methylamine methyltransferase transcripts. A dedicated tRNA(CUA) for pyrrolysine, tRNA(Pyl), is charged by a pyrrolysyl-tRNA synthetase with pyrrolysine.

The direct genetic encoding of pyrrolysine.

Pyrrolysine is an amino acid encoded by the amber codon in genes required for methylamine utilization by members of the Methanosarcinaceae. Pyrrolysine and selenocysteine share the distinction of being the only two non-canonical amino acids that have entered natural genetic codes. Recent experiments have shown that encoding of pyrrolysine, unlike that of selenocysteine, also shares an important trait of the original set of twenty amino acids.

The residue mass of L-pyrrolysine in three distinct methylamine methyltransferases.

Single in-frame amber (UAG) codons are found in the genes encoding MtmB, MtbB, or MttB, the methyltransferases initiating methane formation from monomethylamine, dimethylamine, or trimethylamine, respectively, in certain Archaea. The crystal structure of MtmB demonstrated that the amber codon codes for pyrrolysine, the 22nd genetically encoded amino acid found in nature. Previous attempts to visualize the amber-encoded residue by mass spectrometry identified only lysine, leaving information on the existence and structure of pyrrolysine resting entirely on crystallography of a single protein.

Function of genetically encoded pyrrolysine in corrinoid-dependent methylamine methyltransferases.

Methanogenesis from trimethylamine, dimethylamine or monomethylamine is initiated by a series of corrinoid-dependent methyltransferases. The non-homologous genes encoding the full-length methyltransferases each possess an in-frame UAG (amber) codon that does not terminate translation. The amber codon is decoded by a dedicated tRNA, and corresponds to the novel amino acid pyrrolysine in one of the methyltransferases, indicating pyrrolysine to be the 22nd genetically encoded amino acid.

Reactivity and chemical synthesis of L-pyrrolysine- the 22(nd) genetically encoded amino acid.

L-pyrrolysine, the 22(nd) genetically encoded amino acid, was previously deduced to be (4R, 5R)-4-substituted-pyrroline-5-carboxylate attached to the epsilon-nitrogen of lysine based on the crystal structure of the M. barkeri monomethylamine methyltransferase (MtmB). To confirm L-pyrrolysine's identity, structures of MtmB have been determined following treatment with hydroxylamine, N-methylhydroxylamine, or dithionite.