about
The origin, source, and cycling of methane in deep crystalline rock biosphereExploring Hydrogenotrophic Methanogenesis: a Genome Scale Metabolic Reconstruction of Methanococcus maripaludisDiscovery of Multiple Modified F430 Coenzymes in Methanogens and Anaerobic Methanotrophic Archaea Suggests Possible New Roles for F430 in NatureGenetic resources for methane production from biomass described with the Gene Ontology.Phosphoproteomic analysis of Methanohalophilus portucalensis FDF1(T) identified the role of protein phosphorylation in methanogenesis and osmoregulationLong-term monitoring reveals stable and remarkably similar microbial communities in parallel full-scale biogas reactors digesting energy crops.Novel molecular markers for the detection of methanogens and phylogenetic analyses of methanogenic communities.High resolution depth distribution of Bacteria, Archaea, methanotrophs, and methanogens in the bulk and rhizosphere soils of a flooded rice paddy.Effect of Nickel Levels on Hydrogen Partial Pressure and Methane Production in Methanogens.Trace Elements Induce Predominance among Methanogenic Activity in Anaerobic Digestion.Solute Concentrations Influence Microbial Methanogenesis in Coal-bearing Strata of the Cherokee Basin, USA.Heterologous Production of an Energy-Conserving Carbon Monoxide Dehydrogenase Complex in the Hyperthermophile Pyrococcus furiosus.Metaproteomics and metabolomics analyses of chronically petroleum-polluted sites reveal the importance of general anaerobic processes uncoupled with degradation.Light-driven carbon dioxide reduction to methane by nitrogenase in a photosynthetic bacteriumA RuBisCO-mediated carbon metabolic pathway in methanogenic archaea.The Effects of Perchlorates on the Permafrost Methanogens: Implication for Autotrophic Life on Mars.Biogas Production: Microbiology and Technology.Genomic analysis of methanogenic archaea reveals a shift towards energy conservationCas9-mediated genome editing in the methanogenic archaeon Methanosarcina acetivorans.Non-autotrophic methanogens dominate in anaerobic digesters.Response of Deep Subsurface Microbial Community to Different Carbon Sources and Electron Acceptors during ∼2 months Incubation in Microcosms.CO2 utilization via a novel anaerobic bioprocess configuration with simulated gas mixture and real stack gas samples.Archaeal communities of Arctic methane-containing permafrost.Stratification of Diversity and Activity of Methanogenic and Methanotrophic Microorganisms in a Nitrogen-Fertilized Italian Paddy Soil.In Vitro Response of Rumen Microbiota to the Antimethanogenic Red Macroalga Asparagopsis taxiformis.Flavin-Based Electron Bifurcation, Ferredoxin, Flavodoxin, and Anaerobic Respiration With Protons (Ech) or NAD+ (Rnf) as Electron Acceptors: A Historical Review.Optimization of Expression and Purification of Recombinant Archeoglobus fulgidus F420H2:NADP+ Oxidoreductase, an F420 Cofactor Dependent Enzyme.Assessing Methanogenic Archaeal Community in Full Scale Anaerobic Sludge Digester Systems in Dubai, United Arab Emirates.The diversity of hydrogen-producing bacteria and methanogens within an in situ coal seam
P2860
Q26800009-6EE73FA7-28E7-4382-954B-024CBA0E6103Q28595488-FC522184-3019-4B1C-907D-5E7FBA82B28BQ29543353-0BA2BB04-F532-4290-9B96-DD2666EE901FQ30880353-D9B6BCA4-F33F-4182-9B3C-BB7DF92A6657Q31111333-34F8C098-BF7A-4078-A824-1CFF82E51339Q35575960-0E1A8B84-BAE6-45F6-9B9D-7694166B5D8CQ35718216-F175AB00-F482-4068-BE2C-68CF1134EC68Q35778007-AB152565-B63D-405B-B9A1-2B03D93D65B3Q36228579-125E476B-81DE-4D97-A20D-060E8105DABFQ36233122-C0FA7130-A635-41F9-B314-1EFD700F0BB7Q36290860-3E7DA750-D71F-4F5B-93EC-F9DE10CC979BQ36516281-EBFA594C-271F-4DFF-BAA0-72A23CE4B01EQ37152609-DAAD1CAB-7E93-4B1A-950E-552D71514921Q37247738-6209AABF-4D97-428B-88E0-86524DDBD087Q37591297-61C91369-1270-44DE-B11D-F2967D20FA86Q38446051-41EC18FC-D382-4E86-8CA4-94712225F13CQ38901720-20E90A06-C4BD-46F1-B561-C7B13C6E4B6BQ41466638-05B5CBB2-599E-47FE-ACFF-4CAB8A0634DCQ41749819-E7855896-90D5-4AC3-A8FB-0E8A116A973DQ42267398-5D2E3542-2A14-4DFB-A8C9-5470746B8C8DQ42320732-F41CBED6-C252-4241-B781-648FEFC2DFD6Q46260884-0F650E76-A0E5-4C8C-B329-A42A81BB1C77Q46531323-9F66F1D2-BABF-48F1-9E7F-5FE7DD98DC80Q46726960-54121588-405F-43CB-80BE-E1881D5309D3Q47581423-A26C22F6-F836-4E80-BB25-5AE9EC6EE737Q51733127-DB3AA620-2EA0-4E2D-BD96-8B51A8364287Q54258360-B6CCFF8E-67A2-4BC7-9091-6F12CEB5921EQ54996221-695826AC-D545-4C63-A1FA-C41B9BCAD5E9Q58757935-CAC07CA0-C30A-40AA-BA97-25F255C8AD3B
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Metabolic versatility in methanogens.
@en
type
label
Metabolic versatility in methanogens.
@en
prefLabel
Metabolic versatility in methanogens.
@en
P1476
Metabolic versatility in methanogens.
@en
P2093
John A Leigh
Kyle C Costa
P356
10.1016/J.COPBIO.2014.02.012
P577
2014-03-21T00:00:00Z