Implications of streamlining theory for microbial ecology.
about
Microbial diversity--exploration of natural ecosystems and microbiomesEcophysiology of an uncultivated lineage of Aigarchaeota from an oxic, hot spring filamentous 'streamer' community.Beyond 16S rRNA Community Profiling: Intra-Species Diversity in the Gut MicrobiotaA network-based approach to disturbance transmission through microbial interactionsGlycoside Hydrolases across Environmental Microbial CommunitiesAn Enrichment of CRISPR and Other Defense-Related Features in Marine Sponge-Associated Microbial MetagenomesDid Viruses Evolve As a Distinct Supergroup from Common Ancestors of Cells?A Model of Genome Size Evolution for Prokaryotes in Stable and Fluctuating Environments.In silico screening for candidate chassis strains of free fatty acid-producing cyanobacteria.Changes in Microbial Plankton Assemblages Induced by Mesoscale Oceanographic Features in the Northern Gulf of Mexico.A taxonomic framework for emerging groups of ecologically important marine gammaproteobacteria based on the reconstruction of evolutionary relationships using genome-scale data.Bacterial Biogeography across the Amazon River-Ocean Continuum.Sustaining Rare Marine Microorganisms: Macroorganisms As Repositories and Dispersal Agents of Microbial Diversity.The Evolution of Bacterial Genome Architecture.Candidatus Mycoplasma girerdii replicates, diversifies, and co-occurs with Trichomonas vaginalis in the oral cavity of a premature infant.Microbiome of Trichodesmium Colonies from the North Pacific Subtropical GyreA Viral Immunity Chromosome in the Marine Picoeukaryote, Ostreococcus tauriExperimental Evolution of Metabolic Dependency in Bacteria.Evolutionary ecology of the marine Roseobacter cladeAdaptation of an abundant Roseobacter RCA organism to pelagic systems revealed by genomic and transcriptomic analyses.Average genome size estimation improves comparative metagenomics and sheds light on the functional ecology of the human microbiomeWhat difference does it make if viruses are strain-, rather than species-specific?Resistant microbial cooccurrence patterns inferred by network topology.Microbial metagenomics in the Baltic Sea: Recent advancements and prospects for environmental monitoringAuxotrophy and intrapopulation complementary in the 'interactome' of a cultivated freshwater model community.Ecosystem productivity is associated with bacterial phylogenetic distance in surface marine waters.The physiology and ecological implications of efficient growth.SAR11 lipid renovation in response to phosphate starvation.Microbial metagenomes from three aquifers in the Fennoscandian shield terrestrial deep biosphere reveal metabolic partitioning among populations.Lipid remodelling is a widespread strategy in marine heterotrophic bacteria upon phosphorus deficiency.Co-occurrence of resistance genes to antibiotics, biocides and metals reveals novel insights into their co-selection potential.The global ocean microbiome.Metagenome-assembled genomes uncover a global brackish microbiomeThe reduced genomes of Parcubacteria (OD1) contain signatures of a symbiotic lifestyleAre freshwater bacterioplankton indifferent to variable types of amino acid substrates?Low diversity of planktonic bacteria in the tropical ocean.Gene Loss and Horizontal Gene Transfer Contributed to the Genome Evolution of the Extreme Acidophile "Ferrovum".Endosymbiont evolution: predictions from theory and surprises from genomes.Metabolic Coevolution in the Bacterial Symbiosis of Whiteflies and Related Plant Sap-Feeding Insects.Three-Dimensional Structure of the Ultraoligotrophic Marine Bacterium "Candidatus Pelagibacter ubique"
P2860
Q26776351-43E1700F-42D3-42FB-93E6-83D013E2520BQ27322161-07DB265F-F917-478B-BF3E-EE908E2BED88Q28069618-285CFCC4-D91B-41B9-8888-0407BF517557Q28084823-BA245B52-E10A-4BA1-A473-BD50A0A232F5Q28555227-54ED23E2-B77E-43B2-AF8F-F82676138DB6Q28596229-C6D3BC66-CB97-45D7-AAAA-075C2ACA775CQ28596341-AD0EF9CE-9FDE-4DA9-9C8A-D86456B61969Q28608100-1EF0A0D3-0641-46A3-BDD0-5DE1CDC8A0AEQ30379530-3858DCAD-7670-40A2-BC26-07DA574E8325Q30402725-1FE756E8-3159-4E3A-B0C3-F5C00EC190C8Q30637821-B3A0E9BB-70F7-46EE-ABBA-14E787D3C889Q33715407-D1C137DE-C3CD-4416-881F-C36851AFA1EDQ33735731-52101B0C-6318-4167-B44A-BD78FEAC48FAQ33736659-25927121-FDDE-4E94-BA06-3D283DE44FF3Q33812805-45D73482-DEEE-4AEB-9EEB-B758B352B5BCQ33875553-1AB364FB-B26A-447E-8699-7EAC575F9797Q34047569-7772B10F-2EAD-43A8-A5A0-51A75DD05B4DQ34047612-7D2D2C5B-2CB1-4E49-8E6C-C939E9DD1159Q34592403-8F7040CD-DA1C-4F5D-AAF7-03A54FCB2DA3Q35002675-BDAAE62D-FCFB-4DCD-8EB9-705617D0D8C3Q35317726-C1DB6D2D-BA16-458A-93AF-7550FC53FB40Q35489225-DE44455D-6B23-4416-BF7B-68B1646CA4D7Q35541062-9E2C5D3A-C70C-4DDA-9E42-62683AFC216DQ35645614-C8EF8736-4DF5-4D4E-BE08-EDCB4FE1C17EQ35693109-1B65A857-E124-408C-A8FB-C742375B6BEBQ35750792-8AC2BB9E-DD87-4552-AC5D-8C015066F1C0Q35774441-B43FF9DB-C950-4EC7-835B-C99299E34253Q35796061-196250A0-BAC9-4626-9749-B3513D3FCDDFQ35814319-18FC0A2F-BDC9-4333-815F-D010E7BA85AEQ35840702-35F35BFC-794D-43C7-804B-D6EF38A77DC6Q35844047-B63FE4D9-ABA1-4BAB-8B97-975154EBBC26Q35867130-22C7084D-28D3-415A-87AB-5E63583C923EQ35868780-5DB33B35-9CC9-4027-8B02-16767F02C49FQ35869002-EB34069F-4281-4D1E-A2BC-3AE3CC3BF948Q35887309-A404ADDB-DB89-4765-B1F3-E680C732F8B5Q35889757-CEDD2AEF-E296-4DF5-ACE1-DD983EBA45EAQ36052601-FF54B651-D18F-4760-B9FE-1936FB68321DQ36143177-79ABACE8-4B44-4E69-BF3A-DAADC4AF438CQ36166688-7F092292-0017-4070-9258-8FE6DD07C315Q36190511-24243CE9-0AE4-44FD-B3D9-4710F56EC458
P2860
Implications of streamlining theory for microbial ecology.
description
2014 nî lūn-bûn
@nan
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
2014年论文
@zh
2014年论文
@zh-cn
name
Implications of streamlining theory for microbial ecology.
@ast
Implications of streamlining theory for microbial ecology.
@en
type
label
Implications of streamlining theory for microbial ecology.
@ast
Implications of streamlining theory for microbial ecology.
@en
prefLabel
Implications of streamlining theory for microbial ecology.
@ast
Implications of streamlining theory for microbial ecology.
@en
P2093
P2860
P356
P1433
P1476
Implications of streamlining theory for microbial ecology.
@en
P2093
Ben Temperton
J Cameron Thrash
Stephen J Giovannoni
P2860
P2888
P304
P356
10.1038/ISMEJ.2014.60
P577
2014-04-17T00:00:00Z
P5875
P6179
1041039430