Showing papers on "Methanosarcina barkeri published in 2009"

Genetic Encoding and Labeling of Aliphatic Azides and Alkynes in Recombinant Proteins via a Pyrrolysyl-tRNA Synthetase/tRNACUA Pair and Click Chemistry

Abstract: We demonstrate that an orthogonal Methanosarcina barkeri MS pyrrolysyl-tRNA synthetase/tRNA(CUA) pair directs the efficient, site-specific incorporation of N6-[(2-propynyloxy)carbonyl]-L-lysine, containing a carbon-carbon triple bond, and N6-[(2-azidoethoxy)carbonyl]-L-lysine, containing an azido group, into recombinant proteins in Escherichia coli. Proteins containing the alkyne functional group are labeled with an azido biotin and an azido fluorophore, via copper catalyzed [3+2] cycloaddition reactions, to produce the corresponding triazoles in good yield. The methods reported are useful for the site-specific labeling of recombinant proteins and may be combined with mutually orthogonal methods of introducing unnatural amino acids into proteins as well as with chemically orthogonal methods of protein labeling. This should allow the site specific incorporation of multiple distinct probes into proteins and the control of protein topology and structure by intramolecular orthogonal conjugation reactions.

Effect of substrate concentration on carbon isotope fractionation during acetoclastic methanogenesis by Methanosarcina barkeri and M. acetivorans and in rice field soil.

Abstract: Methanosarcina is the only acetate-consuming genus of methanogenic archaea other than Methanosaeta and thus is important in methanogenic environments for the formation of the greenhouse gases methane and carbon dioxide. However, little is known about isotopic discrimination during acetoclastic CH(4) production. Therefore, we studied two species of the Methanosarcinaceae family, Methanosarcina barkeri and Methanosarcina acetivorans, and a methanogenic rice field soil amended with acetate. The values of the isotope enrichment factor (epsilon) associated with consumption of total acetate (epsilon(ac)), consumption of acetate-methyl (epsilon(ac-methyl)) and production of CH(4) (epsilon(CH4)) were an epsilon(ac) of -30.5 per thousand, an epsilon(ac-methyl) of -25.6 per thousand, and an epsilon(CH4) of -27.4 per thousand for M. barkeri and an epsilon(ac) of -35.3 per thousand, an epsilon(ac-methyl) of -24.8 per thousand, and an epsilon(CH4) of -23.8 per thousand for M. acetivorans. Terminal restriction fragment length polymorphism of archaeal 16S rRNA genes indicated that acetoclastic methanogenic populations in rice field soil were dominated by Methanosarcina spp. Isotope fractionation determined during acetoclastic methanogenesis in rice field soil resulted in an epsilon(ac) of -18.7 per thousand, an epsilon(ac-methyl) of -16.9 per thousand, and an epsilon(CH4) of -20.8 per thousand. However, in rice field soil as well as in the pure cultures, values of epsilon(ac) and epsilon(ac-methyl) decreased as acetate concentrations decreased, eventually approaching zero. Thus, isotope fractionation of acetate carbon was apparently affected by substrate concentration. The epsilon values determined in pure cultures were consistent with those in rice field soil if the concentration of acetate was taken into account.

Hydrogen is a preferred intermediate in the energy-conserving electron transport chain of Methanosarcina barkeri

Abstract: Methanogens use an unusual energy-conserving electron transport chain that involves reduction of a limited number of electron acceptors to methane gas. Previous biochemical studies suggested that the proton-pumping F420H2 dehydrogenase (Fpo) plays a crucial role in this process during growth on methanol. However, Methanosarcina barkeri Δfpo mutants constructed in this study display no measurable phenotype on this substrate, indicating that Fpo plays a minor role, if any. In contrast, Δfrh mutants lacking the cytoplasmic F420-reducing hydrogenase (Frh) are severely affected in their ability to grow and make methane from methanol, and double Δfpo/Δfrh mutants are completely unable to use this substrate. These data suggest that the preferred electron transport chain involves production of hydrogen gas in the cytoplasm, which then diffuses out of the cell, where it is reoxidized with transfer of electrons into the energy-conserving electron transport chain. This hydrogen-cycling metabolism leads directly to production of a proton motive force that can be used by the cell for ATP synthesis. Nevertheless, M. barkeri does have the flexibility to use the Fpo-dependent electron transport chain when needed, as shown by the poor growth of the Δfrh mutant. Our data suggest that the rapid enzymatic turnover of hydrogenases may allow a competitive advantage via faster growth rates in this freshwater organism. The mutant analysis also confirms the proposed role of Frh in growth on hydrogen/carbon dioxide and suggests that either Frh or Fpo is needed for aceticlastic growth of M. barkeri.

Differences in Hydrogenase Gene Expression between Methanosarcina acetivorans and Methanosarcina barkeri

Abstract: Methanosarcina acetivorans C2A encodes three putative hydrogenases, including one cofactor F420-linked (frh) and two methanophenazine-linked (vht) enzymes. Comparison of the amino acid sequences of these putative hydrogenases to those of Methanosarcina barkeri and Methanosarcina mazei shows that each predicted subunit contains all the known residues essential for hydrogenase function. The DNA sequences upstream of the genes in M. acetivorans were aligned with those in other Methanosarcina species to identify conserved transcription and translation signals. The M. acetivorans vht promoter region is well conserved among the sequenced Methanosarcina species, while the second vht-type homolog (here called vhx) and frh promoters have only limited similarity. To experimentally determine whether these promoters are functional in vivo, we constructed and characterized both M. acetivorans and M. barkeri strains carrying reporter gene fusions to each of the M. acetivorans and M. barkeri hydrogenase promoters. Generally, the M. acetivorans gene fusions are not expressed in either organism, suggesting that cis-acting mutations inactivated the M. acetivorans promoters. The M. barkeri hydrogenase gene fusions, on the other hand, are expressed in both organisms, indicating that M. acetivorans possesses the machinery to express hydrogenases, although it does not express its own hydrogenases. These data are consistent with specific inactivation of the M. acetivorans hydrogenase promoters and highlight the importance of testing hypotheses generated by using genomic data.

Crystal structures and enzymatic properties of three formyltransferases from archaea: environmental adaptation and evolutionary relationship.

Abstract: Formyltransferase catalyzes the reversible formation of formylmethanofuran from N(5)-formyltetrahydromethanopterin and methanofuran, a reaction involved in the C1 metabolism of methanogenic and sulfate-reducing archaea. The crystal structure of the homotetrameric enzyme from Methanopyrus kandleri (growth temperature optimum 98 degrees C) has recently been solved at 1.65 A resolution. We report here the crystal structures of the formyltransferase from Methanosarcina barkeri (growth temperature optimum 37 degrees C) and from Archaeoglobus fulgidus (growth temperature optimum 83 degrees C) at 1.9 A and 2.0 A resolution, respectively. Comparison of the structures of the three enzymes revealed very similar folds. The most striking difference found was the negative surface charge, which was -32 for the M. kandleri enzyme, only -8 for the M. barkeri enzyme, and -11 for the A. fulgidus enzyme. The hydrophobic surface fraction was 50% for the M. kandleri enzyme, 56% for the M. barkeri enzyme, and 57% for the A. fulgidus enzyme. These differences most likely reflect the adaptation of the enzyme to different cytoplasmic concentrations of potassium cyclic 2,3-diphosphoglycerate, which are very high in M. kandleri (>1 M) and relatively low in M. barkeri and A. fulgidus. Formyltransferase is in a monomer/dimer/tetramer equilibrium that is dependent on the salt concentration. Only the dimers and tetramers are active, and only the tetramers are thermostable. The enzyme from M. kandleri is a tetramer, which is active and thermostable only at high concentrations of potassium phosphate (>1 M) or potassium cyclic 2,3-diphosphoglycerate. Conversely, the enzyme from M. barkeri and A. fulgidus already showed these properties, activity and stability, at much lower concentrations of these strong salting-out salts.

Recognition between tRNASer and archaeal seryl-tRNA synthetases monitored by suppression of bacterial amber mutations.

Abstract: Two dissimilar seryl-tRNA synthetases (SerRSs) exist in Methanosarcina barkeri : one of bacterial type (bMbSerRS) and the other resembling SerRSs present only in methanogenic archaea (mMbSerRS). While the expression of the archaeal bMbSerRS gene in Escherichia coli complements the function of thermolabile SerRS at a nonpermissive temperature, mMbSerRS does not. Our recent X-ray structural analysis of mMbSerRS revealed an idiosyncratic N-terminal domain and a catalytic zinc ion in the active site, identifying methanogenic-type SerRSs as atypical members of the SerRS family. To shed further light on substrate discrimination by methanogenic-type SerRS, we developed an in vivo system in E. coli to study tRNA serylation by mMbSerRS variants. We show that coexpression of the M. barkeri SerRS gene, encoding either bacterial- or methanogenic-type SerRS, with the gene for cognate archaeal suppressor tRNA leads to suppression of bacterial amber mutations, implying that the E. coli translation machinery can use serylated tRNA from methanogenic archaea as a substrate in protein synthesis. Furthermore, because serylation of M. barkeri serine-specific tRNA by endogenous E. coli SerRS is negligible, suppression is entirely dependent on recognition between archaeal partners (mMbSerRS/suppressor tRNASer). Thus, the efficiency of suppression by mMbSerRS variants quantified in the described β-galactosidase-based reporter system, accurately reflects enzymes' serylation propensity obtained by in vitro kinetic measurements.

Effect of a corrinoid on Methanosarcina barkeri DNA synthesis

Abstract: Methanosarcina barkeri is capable of synthesizing large amounts of corrinoids, compounds of the vitamin B12 group, although not cobalamin. In the present work, exogenous cobalamin was demonstrated to upregulate DNA synthesis in M. barkeri cell suspensions incubated under air. The effect is similar to the one in Propionibacterium freudenreichii cells, though less pronounced. The growth of the archaeon under anaerobic conditions was shown to be suppressed by cobalamin and 5,6-dimethylbenzimidazole. The data obtained suggest the presence of a corrinoid-dependent ribonucleotide reductase in the archaeal cells which provides for deoxyribose precursors for DNA biosynthesis independently of the presence of molecular oxygen in the medium. Growth suppression under anoxic conditions by cobalamin and 5,6-dimethylbenzimidazole may be due to a decrease in the concentration of factor III, a polyfunctional corrinoid dominating in M. barkeri cells.