Phylogenomics of Rhodobacteraceae reveals evolutionary adaptation to marine and non-marine habitats.
about
FnrL and Three Dnr Regulators Are Used for the Metabolic Adaptation to Low Oxygen Tension in Dinoroseobacter shibae.Genomic Analysis of the Evolution of Phototrophy among Haloalkaliphilic Rhodobacterales.Plasmid Transfer in the Ocean - A Case Study from the Roseobacter Group.Fixation of CO2 using the ethylmalonyl-CoA pathway in the photoheterotrophic marine bacterium Dinoroseobacter shibae.Adaptation of Surface-Associated Bacteria to the Open Ocean: A Genomically Distinct Subpopulation of Phaeobacter gallaeciensis Colonizes Pacific Mesozooplankton.The Composite 259-kb Plasmid of Martelella mediterranea DSM 17316T-A Natural Replicon with Functional RepABC Modules from Rhodobacteraceae and Rhizobiaceae.Metabolic versatility of a novel N2 -fixing Alphaproteobacterium isolated from a marine oxygen minimum zone.Trajectories and Drivers of Genome Evolution in Surface-Associated Marine Phaeobacter.VICTOR: genome-based phylogeny and classification of prokaryotic viruses.Aestuarium zhoushanense gen. nov., sp. nov., Isolated from the Tidal Flat.Transcriptional regulation of ectoine catabolism in response to multiple metabolic and environmental cues.Genome-Scale Data Call for a Taxonomic Rearrangement of Geodermatophilaceae.100 Days of marine Synechococcus-Ruegeria pomeroyi interaction: A detailed analysis of the exoproteome.One-step production of C6-C8 carboxylates by mixed culture solely grown on CO.Genome-based classification of micromonosporae with a focus on their biotechnological and ecological potential.Comparative Genomics of Thalassobius Including the Description of Thalassobius activus sp. nov., and Thalassobius autumnalis sp. nov.Variability in metagenomic samples from the Puget Sound: Relationship to temporal and anthropogenic impacts.A year in the life of a thrombolite: comparative metatranscriptomics reveals dynamic metabolic changes over diel and seasonal cycles.Genomic comparison of Clostridium species with the potential of utilizing red algal biomass for biobutanol production.Marine microbiology: Roommates in space and time.Microbiome dynamics in a large artificial seawater aquarium.High similarity in the microbiota of cold-water sponges of the Genus Mycale from two different geographical areas.Complete Genome Sequence of Celeribacter baekdonensis Strain LH4, a Thiosulfate-Oxidizing Alphaproteobacterial Isolate from Gulf of Mexico Continental Slope Sediments.Chemiosmotic Energy Conservation in Dinoroseobacter shibae: Proton Translocation Driven by Aerobic Respiration, Denitrification, and Photosynthetic Light Reaction.Editorial: Molecular Ecology and Genetic Diversity of the Roseobacter Clade.Comparative Genomics and Mutational Analysis Reveals a Novel XoxF-Utilizing Methylotroph in the Roseobacter Group Isolated From the Marine Environment.Role of the Extremolytes Ectoine and Hydroxyectoine as Stress Protectants and Nutrients: Genetics, Phylogenomics, Biochemistry, and Structural Analysis.Horizontal operon transfer, plasmids, and the evolution of photosynthesis in RhodobacteraceaeBacterial virulence against an oceanic bloom-forming phytoplankter is mediated by algal DMSPGenome-Based Taxonomic Classification of the Phylum
P2860
Q36363774-BC567E64-EE73-47FB-B6D3-CF4446065294Q40092436-5B76C937-678F-41F5-ADE0-46CF0A29C0DEQ40109052-B09E65D8-84FE-49D0-B814-B6950CDF0122Q40266913-2DCA163B-6546-4BF1-A26A-CCC6D1AB34DAQ41606098-27EEFD69-7F24-4B84-B4BE-98E4F6FFB366Q42363796-BBC112C3-D89A-4F06-A0A2-E76B79A3154FQ46250130-8D34AF3A-8302-409D-9A6C-FD5AC3B90FECQ46250239-A140B2E4-3C73-4918-AEEE-9ECCB9652DBAQ46284338-F88F541B-EEF3-4DD2-A5DE-E59B5EE80FA8Q46307961-0E099BDB-D7BC-4A3A-85D1-AD994618BB13Q46309084-E984A355-DA42-4802-90F7-015177B8BA04Q47194248-CCBCEF62-CE6A-4229-BC6A-95C2EA06BAA4Q47341992-3AF3F9ED-B6F7-414D-9C11-5D060C71CD38Q48231312-E5207AE1-ACC1-4A19-9A29-48E10AD8F815Q48262869-D8EBE5FC-2F30-40FA-855B-1DD5B28A853FQ48503145-97C2D58A-F72C-4A5E-84B1-9CF1257F4AD3Q50041819-D7AAB299-DC84-48DB-AAA8-CA7E0768DB94Q50135862-07D783C5-8371-4C68-94C1-6B93CDEF5414Q50199407-3B87F08A-0416-4965-AA4E-D08A4FAC9DCCQ50496699-1C50B6AF-7B4E-42F1-A172-95EF1C1D7260Q51148469-8AF58647-FE0B-4FA8-BA2A-F6D7D892F0DBQ55045869-3FD96562-8C2C-49CC-A4E8-65E3EFDD44F8Q55175974-07C72744-0E61-4597-A9E3-271A30E163A9Q55176462-5237C474-EFAC-41B7-8C3E-F13902F467DEQ55264385-69E0C7FD-5930-4EA1-A5EA-CCFEA4BBA493Q55399609-A924110F-153A-4BA1-8C7C-5BA693E4ADD8Q55411691-7C17779E-5DF4-40C0-B680-5660672318E8Q58425845-264FC1C8-8CDF-472A-9358-9016203EA5F4Q58569514-ED0E7E1D-0B01-4A8B-ACA8-0DA8922D5028Q58719422-00C6E6EF-711D-419A-B014-205CD498BDE8
P2860
Phylogenomics of Rhodobacteraceae reveals evolutionary adaptation to marine and non-marine habitats.
description
2017 nî lūn-bûn
@nan
2017年の論文
@ja
2017年論文
@yue
2017年論文
@zh-hant
2017年論文
@zh-hk
2017年論文
@zh-mo
2017年論文
@zh-tw
2017年论文
@wuu
2017年论文
@zh
2017年论文
@zh-cn
name
Phylogenomics of Rhodobacterac ...... arine and non-marine habitats.
@en
type
label
Phylogenomics of Rhodobacterac ...... arine and non-marine habitats.
@en
prefLabel
Phylogenomics of Rhodobacterac ...... arine and non-marine habitats.
@en
P2093
P2860
P50
P356
P1433
P1476
Phylogenomics of Rhodobacterac ...... arine and non-marine habitats.
@en
P2093
Jörn Petersen
Marcus Ulbrich
Meinhard Simon
P2860
P2888
P304
P356
10.1038/ISMEJ.2016.198
P50
P577
2017-01-20T00:00:00Z