Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
about
Genome sequence of Candidatus Nitrososphaera evergladensis from group I.1b enriched from Everglades soil reveals novel genomic features of the ammonia-oxidizing archaeaWhither life? Conjectures on the future evolution of biochemistryPhysiological and genomic characterization of two novel marine thaumarchaeal strains indicates niche differentiationBiogeochemical and Microbial Variation across 5500 km of Antarctic Surface Sediment Implicates Organic Matter as a Driver of Benthic Community Structure.New Dimensions in Microbial Ecology-Functional Genes in Studies to Unravel the Biodiversity and Role of Functional Microbial Groups in the EnvironmentMicrobial Surface Colonization and Biofilm Development in Marine EnvironmentsProduction of 3-Hydroxypropionic Acid via the Propionyl-CoA Pathway Using Recombinant Escherichia coli StrainsThe Chthonomonas calidirosea Genome Is Highly Conserved across Geographic Locations and Distinct Chemical and Microbial Environments in New Zealand's Taupō Volcanic ZoneUnderstanding of anesthesia - Why consciousness is essential for life and not based on genes.Microbial Community Response to Simulated Petroleum Seepage in Caspian Sea Sediments.A comparative study revealed first insights into the diversity and metabolisms of the microbial communities in the sediments of Pacmanus and Desmos hydrothermal fieldsChemoautotrophic growth of ammonia-oxidizing Thaumarchaeota enriched from a pelagic redox gradient in the Baltic SeaGenomic and proteomic characterization of "Candidatus Nitrosopelagicus brevis": an ammonia-oxidizing archaeon from the open oceanMalonic semialdehyde reductase from the archaeon Nitrosopumilus maritimus is involved in the autotrophic 3-hydroxypropionate/4-hydroxybutyrate cycle.Differential contributions of ammonia oxidizers and nitrite oxidizers to nitrification in four paddy soilsThe glyoxylate shunt is essential for CO2-requiring oligotrophic growth of Rhodococcus erythropolis N9T-4.Functional Classification of Uncultured "Candidatus Caldiarchaeum subterraneum" Using the Maple System.Comparative Genomics of a Bacterivorous Green Alga Reveals Evolutionary Causalities and Consequences of Phago-Mixotrophic Mode of Nutrition.Confounding effects of oxygen and temperature on the TEX86 signature of marine ThaumarchaeotaIntegrated In Silico Analysis of Pathway Designs for Synthetic Photo-Electro-Autotrophy.NmPin from the marine thaumarchaeote Nitrosopumilus maritimus is an active membrane associated prolyl isomerase.Two pathways for glutamate biosynthesis in the syntrophic bacterium Syntrophus aciditrophicus.Microbial nitrous oxide emissions in dryland ecosystems: mechanisms, microbiome and mitigation.A novel ammonia-oxidizing archaeon from wastewater treatment plant: Its enrichment, physiological and genomic characteristics.Metabolic potential of fatty acid oxidation and anaerobic respiration by abundant members of Thaumarchaeota and Thermoplasmata in deep anoxic peat.Influence of ammonia oxidation rate on thaumarchaeal lipid composition and the TEX86 temperature proxy.Responses of soil hydrolytic enzymes, ammonia-oxidizing bacteria and archaea to nitrogen applications in a temperate grassland in Inner MongoliaDeveloping a genetic manipulation system for the Antarctic archaeon, Halorubrum lacusprofundi: investigating acetamidase gene function.Proteomics and comparative genomics of Nitrososphaera viennensis reveal the core genome and adaptations of archaeal ammonia oxidizers.Two distinct pools of B12 analogs reveal community interdependencies in the ocean.Integration of Metagenomic and Stable Carbon Isotope Evidence Reveals the Extent and Mechanisms of Carbon Dioxide Fixation in High-Temperature Microbial Communities.Hydrography shapes amoA containing Thaumarcheota in the coastal waters off central Chile.Lipids as paleomarkers to constrain the marine nitrogen cycleA synthetic pathway for the fixation of carbon dioxide in vitro.CO2 assimilation strategies in stratified lakes: Diversity and distribution patterns of chemolithoautotrophs.Chemotaxonomic characterisation of the thaumarchaeal lipidome.Integrated metabolism in sponge-microbe symbiosis revealed by genome-centered metatranscriptomics.Integrated structural biology and molecular ecology of N-cycling enzymes from ammonia-oxidizing archaea.Genome and epigenome of a novel marine Thaumarchaeota strain suggest viral infection, phosphorothioation DNA modification and multiple restriction systems.Ecological Energetic Perspectives on Responses of Nitrogen-Transforming Chemolithoautotrophic Microbiota to Changes in the Marine Environment.
P2860
Q21131994-1A58799A-5B29-4916-BB0C-82E1DEC44850Q26739674-35219A15-A478-4CA9-B752-4224CE65703BQ27322438-31DD125F-9D10-4A08-8E3A-CEE25DFA5F35Q27324958-3AD88092-0DA3-4AA7-8D2C-CA38955BA47AQ28067788-9FE9C66E-F449-4853-98F6-ABF3239EE0BCQ28083033-C1DC5F99-DF57-4142-B007-2DFA636F25DEQ28552481-7C1CAB5C-3A14-42C0-B8E3-386E2C2ECAB0Q28829107-94206A13-BC76-48FD-8E9D-469D66252E59Q30396974-5CE561B6-5A9D-40C6-B57D-4F49FA83D0C5Q30847283-310FC830-EA3F-479F-8051-7CCA2D4DDBDAQ33898638-FBBD2204-0C1A-474B-A5B8-EB29975E9177Q34970060-760EB995-2B8F-41EC-81A2-37018C85148AQ35037866-11020665-1476-4250-844D-5C05E3D6EE52Q35075137-20768070-2CD6-4BFB-B44E-A08C9E9F1EC0Q35535988-ECD41088-162D-470F-957C-59B80B29ECF9Q35573459-E58CCAE9-B50B-43B0-B8BB-6DA9737CA860Q35702643-961DCE49-FC9B-4F5F-8305-7FC4E20D264FQ35725420-F39A86D6-1582-4778-A0C3-8DC929142E10Q36055467-A10A7DB5-F8B0-4AFC-BA07-C33238835363Q36059744-467ED371-6D95-4FC0-91FB-49E549F27E44Q36062775-73487177-A750-4FF2-8B29-96E955EC9C6DQ36279499-B2B41C52-30FC-4DA8-912F-2F84B58ECE01Q36368777-38E1252B-CC38-477E-82D6-4C20BF3B2C77Q36748272-428133BA-04E3-45A3-8CB5-E4FCE0424D8CQ36756387-0C4DCD64-97FC-4DBA-9A6D-E4249E02F3CEQ37102418-E26FC01D-4A89-4C4E-A1B8-F9579A7250A9Q37232890-C8E1F60D-B2D7-4BAB-8068-8FD020DFE306Q37314718-F660DD87-C8BF-4781-B152-0FE250026188Q37493374-AD26E0EA-8ECB-442B-BEBF-77D868D52710Q37589939-C51120DE-3877-4BC7-8F06-5DB70758A2A4Q37622107-977D8815-FBF4-465D-821A-7EA83837BB74Q38610594-BC083621-FB45-4DAE-B344-3FBFDB4B2D78Q38763695-AA7CAB80-DC52-42B5-9CEC-449D1280B257Q38794278-2AE96FC3-0F21-4D47-9FE0-A50569FAEC3EQ38802748-C26EEF47-0FDE-4EA1-8CAD-708DDD90FFE5Q38832015-82F2276F-C49D-4E49-9E15-9A443921438AQ38879767-520D0F6A-601F-4811-86B4-7EDE2373FC1BQ39414592-28C129DE-EAE1-43F1-A81A-E9C41698CF42Q40238989-C946A538-E5D4-4EDC-8D0C-64EFCB42E129Q41011349-DE1A0737-47D3-4F0F-A0BD-C28B5A08136B
P2860
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
description
2014 nî lūn-bûn
@nan
2014 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2014年の論文
@ja
2014年論文
@yue
2014年論文
@zh-hant
2014年論文
@zh-hk
2014年論文
@zh-mo
2014年論文
@zh-tw
2014年论文
@wuu
name
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@ast
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@en
type
label
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@ast
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@en
prefLabel
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@ast
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@en
P2093
P2860
P50
P356
P1476
Ammonia-oxidizing archaea use the most energy-efficient aerobic pathway for CO2 fixation.
@en
P2093
Daniel M Schubert
David A Stahl
Lennart Schada von Borzyskowski
Sonja Standfest
Thomas Schwander
P2860
P304
P356
10.1073/PNAS.1402028111
P407
P577
2014-05-19T00:00:00Z