Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
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Light-Dependent Aerobic Methane Oxidation Reduces Methane Emissions from Seasonally Stratified LakesA Rare Glimpse of Paleoarchean Life: Geobiology of an Exceptionally Preserved Microbial Mat Facies from the 3.4 Ga Strelley Pool Formation, Western AustraliaStable Isotope Phenotyping via Cluster Analysis of NanoSIMS Data As a Method for Characterizing Distinct Microbial Ecophysiologies and Sulfur-Cycling in the EnvironmentChemical microenvironments and single-cell carbon and nitrogen uptake in field-collected colonies of Trichodesmium under different pCO2.Oxygenic photosynthesis as a protection mechanism for cyanobacteria against iron-encrustation in environments with high Fe(2+) concentrations.Unicellular cyanobacterium symbiotic with a single-celled eukaryotic alga.Anaerobic degradation of propane and butane by sulfate-reducing bacteria enriched from marine hydrocarbon cold seepsResponses of the coastal bacterial community to viral infection of the algae Phaeocystis globosa.Chemoautotrophic growth of ammonia-oxidizing Thaumarchaeota enriched from a pelagic redox gradient in the Baltic SeaPhenotypic heterogeneity in metabolic traits among single cells of a rare bacterial species in its natural environment quantified with a combination of flow cell sorting and NanoSIMS.N2-fixation, ammonium release and N-transfer to the microbial and classical food web within a plankton community.The effect of nutrients on carbon and nitrogen fixation by the UCYN-A-haptophyte symbiosis.Methane oxidation coupled to oxygenic photosynthesis in anoxic watersHeavy water and (15) N labelling with NanoSIMS analysis reveals growth rate-dependent metabolic heterogeneity in chemostatsCell-specific nitrogen- and carbon-fixation of cyanobacteria in a temperate marine system (Baltic Sea).Surviving anoxia in marine sediments: The metabolic response of ubiquitous benthic foraminifera (Ammonia tepida).Mycelium-mediated transfer of water and nutrients stimulates bacterial activity in dry and oligotrophic environments.Trace incorporation of heavy water reveals slow and heterogeneous pathogen growth rates in cystic fibrosis sputum.Use of carbon monoxide and hydrogen by a bacteria-animal symbiosis from seagrass sedimentsSuperposition of Individual Activities: Urea-Mediated Suppression of Nitrate Uptake in the Dinoflagellate Prorocentrum minimum Revealed at the Population and Single-Cell Levels.Quantitative imaging of subcellular metabolism with stable isotopes and multi-isotope imaging mass spectrometry.Linking environmental processes to the in situ functioning of microorganisms by high-resolution secondary ion mass spectrometry (NanoSIMS) and scanning transmission X-ray microscopy (STXM).Autotrophic and heterotrophic acquisition of carbon and nitrogen by a mixotrophic chrysophyte established through stable isotope analysisPhenotypic heterogeneity driven by nutrient limitation promotes growth in fluctuating environments.The small unicellular diazotrophic symbiont, UCYN-A, is a key player in the marine nitrogen cycle.Measuring carbon and N2 fixation in field populations of colonial and free-living unicellular cyanobacteria using nanometer-scale secondary ion mass spectrometry(1).Artificial electron acceptors decouple archaeal methane oxidation from sulfate reduction.Quantifying element incorporation in multispecies biofilms using nanoscale secondary ion mass spectrometry image analysis.Crenothrix are major methane consumers in stratified lakesEpifluorescence, SEM, TEM and nanoSIMS image analysis of the cold phenotype of Clostridium psychrophilum at subzero temperatures.Viral infection of Phaeocystis globosa impedes release of chitinous star-like structures: quantification using single cell approaches.Interrogating marine virus-host interactions and elemental transfer with BONCAT and nanoSIMS-based methods.Methyl-compound use and slow growth characterize microbial life in 2-km-deep subseafloor coal and shale beds.Metabolic versatility of a novel N2 -fixing Alphaproteobacterium isolated from a marine oxygen minimum zone.Adaptability as the key to success for the ubiquitous marine nitrite oxidizer Nitrococcus.Phosphorus nutrition of Populus × canescens reflects adaptation to high P-availability in the soil.Methods for visualising active microbial benzene degraders in in situ microcosms.Cell-to-cell variation and specialization in sugar metabolism in clonal bacterial populations.Stable-isotope Raman microspectroscopy for the analysis of soil organic matter.Insights into the fundamental physiology of the uncultured Fe-oxidizing bacterium Leptothrix ochracea.
P2860
Q28546670-29AB8627-A256-41E1-92F1-58F2B7049D87Q28602013-E6D5FDE9-9E81-4EAA-8195-4AF043B10399Q28833327-663E9D05-A423-41D6-9A52-E31DF2EDB1E9Q33705737-97748647-A413-464A-98E3-A3CDAB4C07F5Q34116760-2EE56CB3-0E17-414F-889E-6FA3ECEAD5B7Q34301002-9825E88E-12BC-4803-8111-866AD44948BEQ34518547-5042E262-D9DF-4767-8559-C2E13F56C3DFQ34944693-64946592-84E2-44D8-9E57-38FC947C6080Q34970060-8D16E0C5-D949-4A93-A791-8D93F6A0FED6Q35442607-C72116FC-DD2C-4CE1-BF00-DF6D08BA2827Q35742502-43A3841C-00A9-4335-830E-F7E9F5D215ADQ35774492-C673FD0F-40E2-4BDD-8C66-23067C17E6E9Q35972479-7EC5AC1E-FC50-444D-B34B-63A17D0AB23EQ36105231-3B88C294-E57D-47E4-B8DE-67734879FA41Q36151767-BDF81238-A654-42A0-898C-A11A0096CFC2Q36386364-35EC7356-E776-4E4B-82A7-2CE9A7191FCEQ36394730-0E87595A-4C42-4EF6-A02B-BADC257C7CDEQ36483152-D834543C-4268-4815-8818-8DEA4FAE928CQ36554525-6A3ECE82-570B-4FBB-A360-065296361614Q37201851-647B32A7-8A14-4FF7-83E2-813BA9220F83Q37700525-2469EF03-9358-4658-8A83-E7D65B5FD2C1Q37992689-C5CD34DA-5B6E-4C94-88CC-61F5AF4CAF18Q38774972-AF6C84ED-776C-4F84-9A9A-7C5A155354ABQ38826733-929F522D-0473-4B79-9E91-F056A1B1FCA8Q39220957-3F3128E5-F27A-4473-92A7-99BE74566B51Q39895512-CA038C2B-1792-4138-997E-19C08C29B58BQ39970573-1597ADD4-B70B-49E3-AED6-892144490331Q40000888-78BB25FE-2378-4589-921B-FF11BBAE97C4Q41467157-5FF464F7-D367-4AFC-9BD8-C730F11DB876Q41607191-CE6AFF50-2B62-4A38-AAD9-BD7150D152ACQ44125763-2E1ED4BD-22A1-49D8-B9B8-4713434E5527Q45324512-4B91C418-5F57-4797-B54F-1D8344F9C188Q45354348-A6090BFA-2E05-4029-A034-6D0DB0B2ED5EQ46250130-92740C6E-55DA-4182-9C41-B58961C5E2C3Q46267324-AAAB4206-0BC2-4323-8D6B-36A534403EA8Q46273278-54DCB4CB-254C-406E-AB0D-BCF7C6F6DD74Q46842523-BF0D44CD-A759-4708-AD53-AB00914A6890Q47574153-0D5B9D0A-A6E6-468E-88ED-0728A95DFB9FQ47927843-A084E3BA-3F8E-4218-A971-691B0AE593FCQ49914319-FA76587A-E6EA-441A-A638-A1723F3BB41A
P2860
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
description
2012 nî lūn-bûn
@nan
2012 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@ast
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@en
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@nl
type
label
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@ast
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@en
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@nl
prefLabel
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@ast
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@en
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@nl
P2093
P2860
P1476
Look@NanoSIMS--a tool for the analysis of nanoSIMS data in environmental microbiology.
@en
P2093
Birgit Adam
Jana Milucka
Lubos Polerecky
Marcel M M Kuypers
Tomas Vagner
P2860
P304
P356
10.1111/J.1462-2920.2011.02681.X
P577
2012-01-06T00:00:00Z