Availability of ferric iron for microbial reduction in bottom sediments of the freshwater tidal potomac river.
about
Microbial reduction of Fe(III) in acidic sediments: isolation of Acidiphilium cryptum JF-5 capable of coupling the reduction of Fe(III) to the oxidation of glucoseDissimilatory Fe(III) Reduction by the Marine Microorganism Desulfuromonas acetoxidansRelease of arsenic from soil by a novel dissimilatory arsenate-reducing bacterium, Anaeromyxobacter sp. strain PSR-1Direct and Fe(II)-mediated reduction of technetium by Fe(III)-reducing bacteriaControlled cobalt doping in biogenic magnetite nanoparticlesEcophysiological Evidence that Achromatium oxaliferum Is Responsible for the Oxidation of Reduced Sulfur Species to Sulfate in a Freshwater Sediment.Dissimilatory Fe(III) and Mn(IV) reductionBiogeochemical Conditions Favoring Magnetite Formation during Anaerobic Iron ReductionUse of Fe(III) as an electron acceptor to recover previously uncultured hyperthermophiles: isolation and characterization of Geothermobacterium ferrireducens gen. nov., sp. novPhysiological and genomic features of highly alkaliphilic hydrogen-utilizing Betaproteobacteria from a continental serpentinizing siteBacterial and archaeal diversity in an iron-rich coastal hydrothermal field in Yamagawa, Kagoshima, Japan.The Impact of Bacterial Strain on the Products of Dissimilatory Iron Reduction.Rapid Benzene Degradation in Methanogenic Sediments from a Petroleum-Contaminated AquiferFnr (EtrA) acts as a fine-tuning regulator of anaerobic metabolism in Shewanella oneidensis MR-1.Regulation of oxidative stress response by CosR, an essential response regulator in Campylobacter jejuni.Anaerobic benzene biodegradation linked to nitrate reduction.Dissimilatory reduction of Fe(III) and other electron acceptors by a Thermus isolate.Reduction of Fe(III), Mn(IV), and toxic metals at 100 degrees C by Pyrobaculum islandicum.Suboxic deposition of ferric iron by bacteria in opposing gradients of Fe(II) and oxygen at circumneutral pH.The periplasmic 9.6-kilodalton c-type cytochrome of Geobacter sulfurreducens is not an electron shuttle to Fe(III).Life at the energetic edge: kinetics of circumneutral iron oxidation by lithotrophic iron-oxidizing bacteria isolated from the wetland-plant rhizosphereInteractions between the Fe(III)-reducing bacterium Geobacter sulfurreducens and arsenate, and capture of the metalloid by biogenic Fe(II).Oxidation of Polycyclic Aromatic Hydrocarbons under Sulfate-Reducing ConditionsCoupled dynamics of iron and phosphorus in sediments of an oligotrophic coastal basin and the impact of anaerobic oxidation of methane.Growth of thermophilic and hyperthermophilic Fe(III)-reducing microorganisms on a ferruginous smectite as the sole electron acceptor.Extracellular iron reduction is mediated in part by neutral red and hydrogenase in Escherichia coli.Microbial degradation of isosaccharinic acid at high pH.Extracellular electron transport-mediated Fe(III) reduction by a community of alkaliphilic bacteria that use flavins as electron shuttles.Isolation of Geobacter species from diverse sedimentary environments.Diversity, metabolic properties and arsenic mobilization potential of indigenous bacteria in arsenic contaminated groundwater of West Bengal, IndiaIsolation of microorganisms involved in reduction of crystalline iron(III) oxides in natural environmentsThe impact of gamma radiation on sediment microbial processes.Lactate oxidation coupled to iron or electrode reduction by Geobacter sulfurreducens PCAPhenotypic Characterisation of Shewanella oneidensis MR-1 Exposed to X-Radiation.Composition of Non-Microbially Reducible Fe(III) in Aquatic SedimentsHydrogen and Formate Oxidation Coupled to Dissimilatory Reduction of Iron or Manganese by Alteromonas putrefaciens.Anaerobic Oxidation of Toluene, Phenol, and p-Cresol by the Dissimilatory Iron-Reducing Organism, GS-15Surface multiheme c-type cytochromes from Thermincola potens and implications for respiratory metal reduction by Gram-positive bacteria.Influence of soil minerals on chromium(VI) reduction by sulfide under anoxic conditions.Microbial degradation of toluene under sulfate-reducing conditions and the influence of iron on the process.
P2860
Q24550550-B1EA6EC5-B30B-40A2-8392-2883F4556449Q24569528-979E1EEB-43E2-401F-8054-0E19E653D10BQ24596202-FFB5C243-3BAD-45D4-AF16-402014379864Q28344707-1D5D5C20-D1CE-4FAE-ACF0-838161BBE5BDQ28705683-E8C4ADD6-1DF9-4C35-A811-F22B8A0EEB6FQ28768333-840CB8A8-C51C-476B-A7ED-0CFCFDDB2B10Q28776142-575F4C63-1652-41C7-8781-DE62E81485F9Q28776881-02863934-6E3B-4CBB-A0CA-F9B84B7175CDQ30682913-E1F8CC33-5AE3-42FE-9ACC-51F66D10E584Q30824735-6E0893DB-25D2-404A-9810-678EE4D9E7BCQ31144161-6041FFF6-DD41-4E95-96E2-6224A24A1710Q33551749-70C6EF4B-8399-428A-89E6-9ECE3E1B83F1Q33708555-B0499E47-4E77-4DE9-8B27-61E781835075Q33857730-F02911EE-F23F-43AE-87C2-3BB37841446CQ33979818-84022715-A088-4D95-8332-7D51CCF17130Q33984212-349E8362-7067-4EE9-A5D0-72448921DA5AQ33984456-55650644-1AE0-483B-8FC9-BA6CFD734484Q33986760-53CA833B-1A58-4721-8FCA-B87C33A23CEAQ33989136-D459D192-A9D4-45F1-98C4-6C6DBE69B9E6Q33993358-58C62D49-A1BE-4734-B0AC-A5AE411B7B7DQ34056862-3A96BCB8-E372-42FB-BB83-473FD95FFF9EQ34232230-84125B64-0B34-4FA4-ADCD-E4DDD3768185Q34423478-CA83FF7C-1E52-408A-BF06-97C5E1E572C4Q34693108-087B64C3-4F21-474F-913F-039618ADE0DDQ34709518-38057D95-ECEE-4BF1-ACD4-70F612514A04Q34779304-CE8794E4-1D39-4CFC-9584-71B5AABCA5EDQ35002630-53F12555-0C9A-479A-81BA-7379FBE19D97Q35021137-6BC68CA0-7887-4B21-B5B1-B15C99F52A90Q35190255-5D336CC4-875F-4149-8C96-A8CCE84C846FQ35208118-F98C567E-A82A-4F47-BC03-AB2489F34E9CQ35569594-738596BA-866F-4D7E-A2A9-141593CC3A53Q35595019-D6780A59-F4CD-4700-8137-866D252125EBQ35599212-E8333B32-48DF-4FDF-A918-3D846C7D7264Q35670778-FCD71D77-68E2-4517-AAEC-FBA91C8B9F8DQ35681173-F61193F1-08BA-4339-AA1B-7AF2186E4253Q35733758-6ACCA591-B165-4F28-93A3-BAA84A48EEABQ35738976-C34A9611-17A9-4BF0-8B28-80879AEF9C3FQ35749762-6391134A-5DC2-49C3-AE21-19B3E22D209DQ35782784-F1610079-7DFC-4CC4-9E89-39596F02D470Q35952209-588D8C35-6861-4557-AFEC-EAD6609D76DE
P2860
Availability of ferric iron for microbial reduction in bottom sediments of the freshwater tidal potomac river.
description
1986 nî lūn-bûn
@nan
1986年の論文
@ja
1986年論文
@yue
1986年論文
@zh-hant
1986年論文
@zh-hk
1986年論文
@zh-mo
1986年論文
@zh-tw
1986年论文
@wuu
1986年论文
@zh
1986年论文
@zh-cn
name
Availability of ferric iron fo ...... reshwater tidal potomac river.
@en
type
label
Availability of ferric iron fo ...... reshwater tidal potomac river.
@en
prefLabel
Availability of ferric iron fo ...... reshwater tidal potomac river.
@en
P1476
Availability of ferric iron fo ...... reshwater tidal potomac river.
@en
P2093
Phillips EJ
P2860
P304
P407
P577
1986-10-01T00:00:00Z