Subcellular localization of marine bacterial alkaline phosphatases
about
The transcriptome and proteome of the diatom Thalassiosira pseudonana reveal a diverse phosphorus stress responseRapidly diverging evolution of an atypical alkaline phosphatase (PhoA(aty)) in marine phytoplankton: insights from dinoflagellate alkaline phosphatasesHigh sequence variability, diverse subcellular localizations, and ecological implications of alkaline phosphatase in dinoflagellates and other eukaryotic phytoplanktonCELLO2GO: a web server for protein subCELlular LOcalization prediction with functional gene ontology annotation.Iron limitation of microbial phosphorus acquisition in the tropical North Atlantic.Marine microbial metagenomics: from individual to the environment.Elemental economy: microbial strategies for optimizing growth in the face of nutrient limitation.Bacterial community transcription patterns during a marine phytoplankton bloom.The genes and enzymes of phosphonate metabolism by bacteria, and their distribution in the marine environmentMethane production by phosphate-starved SAR11 chemoheterotrophic marine bacteria.Novel analysis of oceanic surface water metagenomes suggests importance of polyphosphate metabolism in oligotrophic environments.Effect of redox conditions on bacterial community structure in Baltic Sea sediments with contrasting phosphorus fluxesPhylogenetic Characterization of Phosphatase-Expressing Bacterial Communities in Baltic Sea Sediments.Dissolved phosphorus pools and alkaline phosphatase activity in the euphotic zone of the Western north pacific oceanphoD Alkaline Phosphatase Gene Diversity in Soil.Predicted protein subcellular localization in dominant surface ocean bacterioplankton.Differential utilization patterns of dissolved organic phosphorus compounds by heterotrophic bacteria in two mountain lakesProteomic responses of oceanic Synechococcus WH8102 to phosphate and zinc scarcity and cadmium additionsNew insights into bacterial acquisition of phosphorus in the surface ocean.The biodiscovery potential of marine bacteria: an investigation of phylogeny and functionNoncoding and coding transcriptome responses of a marine diatom to phosphate fluctuations.Phosphorus physiological ecology and molecular mechanisms in marine phytoplankton.Phylotype Dynamics of Bacterial P Utilization Genes in Microbialites and Bacterioplankton of a Monomictic Endorheic Lake.Phosphorus depletion in forest soils shapes bacterial communities towards phosphorus recycling systems.Comparative analysis of alkaline phosphatase-encoding genes (phoX) in two contrasting zones of Lake Taihu.Epibionts dominate metabolic functional potential of Trichodesmium colonies from the oligotrophic ocean.An alkaline phosphatase/phosphodiesterase, PhoD, induced by salt stress and secreted out of the cells of Aphanothece halophytica, a halotolerant cyanobacteriumCrystal structure of the Bacillus subtilis phosphodiesterase PhoD reveals an iron and calcium-containing active site.Characterization of the proteomic profiles of the brown tide alga Aureoumbra lagunensis under phosphate- and nitrogen-limiting conditions and of its phosphate limitation-specific protein with alkaline phosphatase activity.A complex iron-calcium cofactor catalyzing phosphotransfer chemistry.Identification and characterization of an extracellular alkaline phosphatase in the marine diatom Phaeodactylum tricornutum.Genome content of uncultivated marine Roseobacters in the surface ocean.Recovery of novel alkaline phosphatase-encoding genes (phoX) from eutrophic Lake Taihu.Prevalence of a calcium-based alkaline phosphatase associated with the marine cyanobacterium Prochlorococcus and other ocean bacteria.Assembly-free metagenomic analysis reveals new metabolic capabilities in surface ocean bacterioplankton.PARTIAL PURIFICATION AND CHARACTERIZATION OF A CALCIUM-DEPENDENT ALKALINE PHOSPHATASE FROM THE CYANOBACTERIUM ARTHROSPIRA PLATENSIS (1).Alkaline Phosphatase Gene Sequence And Transcriptional Regulation By Phosphate Limitation In Amphidinium Carterae (Dinophyceae)(1).In Vitro and in Silico Evidence of Phosphatase Diversity in the Biomineralizing Bacterium Ramlibacter tataouinensis.Soil phoD and phoX alkaline phosphatase gene diversity responds to multiple environmental factors.Role of the phosphatase PhoX in the phosphorus metabolism of the marine bacterium Ruegeria pomeroyi DSS-3.
P2860
Q28481848-1C5C5813-4456-4609-97E8-EE3E9D431288Q28608508-004FD579-3E35-4C50-B835-E8CE85798BB2Q28727669-E9BE06B2-EE1F-4F8D-8026-9A416908AA4BQ33728064-0C71B655-B4C0-48F2-9D2E-A0E95D5379DAQ33754338-A830FE1A-3661-45D2-B715-E787AB78C5E7Q33755903-4185ECA5-916B-40CD-B738-BF5FA9CA96D2Q33911028-5D0438E1-C0FC-4EB7-9A64-BC921EC66131Q34045367-4CAEDA14-DBF3-4B63-A6FB-D6B643E79EF0Q34149896-A8FDB522-C37C-452B-B780-1A44D6DFB64DQ34428166-34FAB74D-91F8-4782-82F8-BDC493E78EDBQ34537995-237E879E-BBB2-4AB6-B381-C6D1988C562AQ35131381-99643EBF-B1F4-4981-9E85-B6B7ECE6EF90Q35589130-D507CA5D-B87F-402D-A43D-6E31337F9552Q35838176-850048B6-3DC4-4B31-991E-10A134F637B6Q36084510-10E5DD6B-32D8-4FE4-B928-36409E213497Q36186100-E4F8736C-5CD4-4799-BB3F-B0C4C0778987Q37084014-EFF6E2D9-F2D7-4836-9057-8379296F4D9CQ37397517-8D607FF2-084A-49DF-82E3-3E62EB7C0B5EQ37482306-7B963740-82DC-4BCC-995B-AF98E85D03C2Q37566837-31A5E6D0-E2BE-4163-A5EB-F62BC3E3FFFCQ38453492-35CA66D8-C3DE-4288-86D1-D69001C6F449Q38778404-26B457FC-D918-41D0-8279-587ACF5D918FQ39545731-B3E79F1F-572A-4347-886B-3ED8117091A1Q40185219-F7FCCD2B-8B5D-4F36-BADD-E74AA705D820Q41445158-91263692-31B6-40A1-9665-1C4F9AF256BDQ41467135-0F0C91BB-ADAE-404C-8C36-77563F3A55FEQ41817540-70765200-DDFE-47CC-8E02-CDDFF872E9B2Q41898025-249DA951-A3E1-464A-9521-346AA28CED1EQ42590939-A6FEED98-DB20-42A8-A6CD-224628A647D5Q42915611-614C7FDD-9FD0-472C-B739-493CCAF3A309Q43498545-1737D357-DB04-4626-AE5F-0ED5F8A96737Q43744374-E9677303-1989-4349-948A-210B85F8921AQ45891806-4D556ECD-9955-4CFC-BBE1-66CA66C31DB8Q46406487-360FF023-9A3A-4C16-928E-8BADD08DB2D3Q46984377-83A7CADC-11CF-4EDE-8349-4D1FAD0B046DQ48050886-595A8661-9492-44B1-8943-A7A741C86386Q48055548-8C7BA793-6218-406B-AD26-4F8AB9E5824DQ49397231-B4EFD7D3-B767-40BE-8A32-2BE1ED9F4AF7Q51396592-671360DB-501F-4999-808F-0A85694D1E46Q53112143-6C6EB8F0-549F-4A74-854E-C1809F1BB6A1
P2860
Subcellular localization of marine bacterial alkaline phosphatases
description
2009 nî lūn-bûn
@nan
2009 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Subcellular localization of marine bacterial alkaline phosphatases
@ast
Subcellular localization of marine bacterial alkaline phosphatases
@en
type
label
Subcellular localization of marine bacterial alkaline phosphatases
@ast
Subcellular localization of marine bacterial alkaline phosphatases
@en
prefLabel
Subcellular localization of marine bacterial alkaline phosphatases
@ast
Subcellular localization of marine bacterial alkaline phosphatases
@en
P2093
P2860
P356
P1476
Subcellular localization of marine bacterial alkaline phosphatases
@en
P2093
Haiwei Luo
Jianjun Hu
Richard A Long
P2860
P304
21219-21223
P356
10.1073/PNAS.0907586106
P407
P577
2009-11-19T00:00:00Z