Ecophysiology of Fe-cycling bacteria in acidic sediments.
about
Iron and zinc exploitation during bacterial pathogenesisCharacterization of Metabolically Active Bacterial Populations in Subseafloor Nankai Trough Sediments above, within, and below the Sulfate-Methane Transition ZoneA microbial oasis in the hypersaline Atacama subsurface discovered by a life detector chip: implications for the search for life on MarsAcidibacter ferrireducens gen. nov., sp. nov.: an acidophilic ferric iron-reducing gammaproteobacterium.Depth-dependent geochemical and microbiological gradients in Fe(III) deposits resulting from coal mine-derived acid mine drainageMicrobial diversity in anaerobic sediments at Rio Tinto, a naturally acidic environment with a high heavy metal content.Identification of Mn(II)-oxidizing bacteria from a low-pH contaminated former uranium mineComparative microbial ecology study of the sediments and the water column of the Río Tinto, an extreme acidic environment.Redox Transformations of Iron at Extremely Low pH: Fundamental and Applied Aspects.The Microbial Ferrous Wheel in a Neutral pH Groundwater Seep.Río tinto: a geochemical and mineralogical terrestrial analogue of Mars.Screening of anaerobic activities in sediments of an acidic environment: Tinto River.Insights into the structure and metabolic function of microbes that shape pelagic iron-rich aggregates ("iron snow").Bacteria diversity, distribution and insight into their role in S and Fe biogeochemical cycling during black shale weathering.Profiling bacterial diversity in a limestone cave of the western Loess Plateau of China.pH influences the importance of niche-related and neutral processes in lacustrine bacterioplankton assemblyAquifer community structure in dependence of lithostratigraphy in groundwater reservoirs.Characterization of pH dependent Mn(II) oxidation strategies and formation of a bixbyite-like phase by Mesorhizobium australicum T-G1Extremophile microbiomes in acidic and hypersaline river sediments of Western Australia.Characterization of the microbial community composition and the distribution of Fe-metabolizing bacteria in a creek contaminated by acid mine drainage.Genome Sequence of the Acidophilic Bacterium Acidocella sp. Strain MX-AZ02.Microbial iron-redox cycling in subsurface environments.Microbial communities in carbonate rocks-from soil via groundwater to rocks.Comparative Study of Bacterial Communities in Nepenthes Pitchers and Their Correlation to Species and Fluid Acidity.Iron transformations induced by an acid-tolerant Desulfosporosinus species.Distinct Anaerobic Bacterial Consumers of Cellobiose-Derived Carbon in Boreal Fens with Different CO2/CH4 Production Ratios.Chemolithotrophic nitrate-dependent Fe(II)-oxidizing nature of actinobacterial subdivision lineage TM3.Adaptation of Acidithiobacillus bacteria to metallurgical wastes and its potential environmental risks.Microbial heterotrophic production in an oligotrophic acidic geothermal lake: responses to organic amendments and terrestrial plant litter.Treatment impacts on temporal microbial community dynamics during phytostabilization of acid-generating mine tailings in semiarid regions.
P2860
Q28082191-4A256984-568F-4740-8665-F61A8DC98703Q28730804-74047B2B-6C7F-46FE-9DB7-D3EA9BB562B0Q28741182-232C10B7-03FD-433F-A8B0-64C4BFFD03D4Q30842260-EB083494-FB3D-4724-9D4E-EED8EECF3B7CQ33646963-2C413716-E9F6-4455-81F1-8ED36FF815D5Q33949377-E0A45A6C-28D3-479B-A523-BB26728003D7Q34057151-E3D63B86-9429-459B-9B42-70DD812EEC71Q34183193-014EE838-1B8F-4BF8-AB32-268E0DBBA99EQ34262888-9FA787A7-4D70-4921-B67F-30E6FDD848EDQ34333032-04430A18-B1C9-4F91-A490-B8F702E73DE7Q34390442-1982D14F-51B2-404B-85DF-4D4AA6C6775EQ34407625-589E4FA2-BCA8-4C67-B491-DC38F2E475A8Q34706498-9172566F-9342-4155-8C16-928B00616453Q35189188-80BA62CC-EB70-4219-8CB2-80219BE6EAA6Q35229026-8481758A-42AC-4F7F-8366-A3C3DD70724AQ35366273-F23F8F14-21D1-4476-98CC-6B580A6E1B2CQ35639904-C8C14B06-146C-4538-8C4C-4745B4377A3DQ35734340-314AE2B8-51DD-4294-AA96-2EFCC5A0939EQ35829373-D8EAFDC4-805F-4908-856A-403A04BCAAAFQ36045354-6B732E64-7845-485B-A55D-787A5F4F7C47Q36601352-1E7ED5CB-CE10-4EC6-A65E-7722CAE0B940Q38061979-FC04C51A-A199-4DDE-8A32-6E97E4A55D9FQ38691476-A5B2CDFE-30ED-49AC-B4C1-7EAD9D8387B9Q39692402-07152B02-E411-49E8-85DC-CE45891FDBBAQ40310769-B01D1161-5340-4081-B7DB-76EDBDAFEDB4Q41858418-BDE42D37-F753-4F43-89E9-988240425127Q43077673-39D6F858-7EC0-4DDD-9866-C32F938496B2Q43334451-3E1FDA6B-1C95-49AB-AF62-07E8C7DA138CQ45229111-9548CA34-5611-4400-A7D9-5B2F80FFBAFCQ47354126-6D6E47C9-CA33-426D-9937-501AE079F838
P2860
Ecophysiology of Fe-cycling bacteria in acidic sediments.
description
2010 nî lūn-bûn
@nan
2010 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@ast
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@en
type
label
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@ast
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@en
prefLabel
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@ast
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@en
P2093
P2860
P356
P1476
Ecophysiology of Fe-cycling bacteria in acidic sediments.
@en
P2093
Kevin B Hallberg
Marco Reiche
Shipeng Lu
Stefan Gischkat
P2860
P304
P356
10.1128/AEM.01931-10
P407
P577
2010-10-22T00:00:00Z