A hypervariable 130-kilobase genomic region of Magnetospirillum gryphiswaldense comprises a magnetosome island which undergoes frequent rearrangements during stationary growth.
about
Comparative genome analysis and genome-guided physiological analysis of Roseobacter litoralisCell biology of prokaryotic organellesCrystallizing the function of the magnetosome membrane mineralization protein Mms6Molecular mechanisms of compartmentalization and biomineralization in magnetotactic bacteriaGenetic and Ultrastructural Analysis Reveals the Key Players and Initial Steps of Bacterial Magnetosome Membrane BiogenesisConservation of proteobacterial magnetosome genes and structures in an uncultivated member of the deep-branching Nitrospira phylum.A genetic strategy for probing the functional diversity of magnetosome formationInsight into the assembly properties and functional organisation of the magnetotactic bacterial actin-like homolog, MamKMobile DNA and evolution in the 21st centuryUncultivated magnetotactic cocci from yuandadu park in beijing, chinaImpact of Static Magnetic Field (SMF) on Microorganisms, Plants and AnimalsBiogenesis of actin-like bacterial cytoskeletal filaments destined for positioning prokaryotic magnetic organellesNonmagnetotactic multicellular prokaryotes from low-saline, nonmarine aquatic environments and their unusual negative phototactic behaviorVisualization and structural analysis of the bacterial magnetic organelle magnetosome using atomic force microscopy.Desulfovibrio magneticus RS-1 contains an iron- and phosphorus-rich organelle distinct from its bullet-shaped magnetosomes.Magnetochrome: a c-type cytochrome domain specific to magnetotatic bacteria.Protecting sausages with bacteria instead of salt.Physiological origin of biogenic magnetic nanoparticles in health and disease: from bacteria to humans.Toward cloning of the magnetotactic metagenome: identification of magnetosome island gene clusters in uncultivated magnetotactic bacteria from different aquatic sedimentsCultivation-independent characterization of 'Candidatus Magnetobacterium bavaricum' via ultrastructural, geochemical, ecological and metagenomic methods.Deletion of the ftsZ-like gene results in the production of superparamagnetic magnetite magnetosomes in Magnetospirillum gryphiswaldense.Comprehensive genetic dissection of the magnetosome gene island reveals the step-wise assembly of a prokaryotic organelleNovel magnetite-producing magnetotactic bacteria belonging to the Gammaproteobacteria.Functional analysis of the magnetosome island in Magnetospirillum gryphiswaldense: the mamAB operon is sufficient for magnetite biomineralization.The MagA protein of Magnetospirilla is not involved in bacterial magnetite biomineralization.Patterns and architecture of genomic islands in marine bacteria.Insight into the evolution of magnetotaxis in Magnetospirillum spp., based on mam gene phylogenyClone libraries and single cell genome amplification reveal extended diversity of uncultivated magnetotactic bacteria from marine and freshwater environments.From bacteria to mollusks: the principles underlying the biomineralization of iron oxide materials.The fate of laterally transferred genes: life in the fast lane to adaptation or death.Evolution of intracellular compartmentalization.Magnetosome-containing bacteria living as symbionts of bivalves.Spatial localizations of Mam22 and Mam12 in the magnetosomes of Magnetospirillum magnetotacticum.Chromosomal instability in enterohaemorrhagic Escherichia coli O157:H7: impact on adherence, tellurite resistance and colony phenotype.MamX encoded by the mamXY operon is involved in control of magnetosome maturation in Magnetospirillum gryphiswaldense MSR-1.The oxygen sensor MgFnr controls magnetite biomineralization by regulation of denitrification in Magnetospirillum gryphiswaldenseThe combination of random mutagenesis and sequencing highlight the role of unexpected genes in an intractable organism.Comparative genome analysis of four magnetotactic bacteria reveals a complex set of group-specific genes implicated in magnetosome biomineralization and functionDynamics of magnetotactic bacteria in a rotating magnetic fieldWhy Close a Bacterial Genome? The Plasmid of Alteromonas Macleodii HOT1A3 is a Vector for Inter-Specific Transfer of a Flexible Genomic Island.
P2860
Q21267183-52F9013C-6A0E-4EB0-8FDE-9A16B986B5F6Q24602228-6E344A5E-826E-4BAD-A84E-90F61931C492Q26747181-06BB0E40-1D62-488C-843C-7A8BF4000310Q26824368-3F4AFF08-8ED3-48AA-98A1-51256F4BB31FQ27308774-780940D0-D86A-424F-9C6E-C385A5F2D553Q28301978-8AE67629-0133-4C1F-A785-6C487B6DF782Q28543002-467BBE17-C671-4C49-AD6B-52F940A3CF54Q28730080-CD9D3EB1-C0DA-4746-8D13-02991527FC6AQ28748605-CFC1F628-F960-43F2-815C-9BD5AF1A8097Q28752474-4290E069-1565-46A1-A653-19A458B4CFDAQ29647485-8FB1ABCE-4015-486D-A167-EBB4B39622FEQ30479355-5FD8B008-502F-483A-8FA3-F4A117FDABA9Q30494492-B1B30AFE-B8F4-423B-9F70-B083EACAB601Q30494967-D986EB66-13C5-4A29-9AEB-B12A5E7C5A7DQ30495390-2A5D51C9-09E2-4418-ABA5-7D4AB1E9CFF9Q30578337-A0156EAA-CFA9-41CC-928E-47C1DA831D61Q33232053-4A8D4DBC-7C2E-4771-8960-7798566780D3Q33365647-8C46D1D2-A751-4A30-A66A-DA6713882311Q33435189-DC98FED6-DB7B-4C50-89C5-75A209CE5212Q33560329-10F6EB97-916E-4122-A6B8-4EC59E483856Q33616924-FD27A6FC-E8DD-4646-B3F3-CC973F2B35E6Q33778027-5EDE036D-BCCB-41D3-AF85-B4D420D54F21Q33966861-C4C1AAB3-2E9D-4982-80B0-AE85B5BA0436Q34063583-19AE6F87-7A7C-40DD-BCE0-DA0CFFD275F4Q34242549-9FD34644-71D5-4CFC-92DB-45992BBDACAAQ34354634-EECFAB66-9C73-42EC-A0FC-6B4A1EBBCBD7Q34366758-127ECE1A-B106-4FB2-A150-5AD345BBAD67Q34459341-8DFB2337-ADC3-45C0-97EE-96338EFD5C45Q34470731-99195635-EBBD-4E82-9CED-7C4A70BA9CD7Q34520049-73D6F201-5B8E-4197-84FF-39D2FD1BBCAAQ34646440-68848B19-DEEA-4848-8330-A94983ADEEA5Q34662111-E953A961-ECEB-48A7-8048-C6E99F486AD1Q34697197-02DDFFC4-488C-4EB3-B5C6-50B2AF1D98CFQ34723420-B942EA07-A3C1-4FF0-8CC9-6722D07B179CQ34982996-2E6D0202-1FC7-4D4E-884D-793FEF65493EQ35184967-9BEE6720-AF88-44FF-B48E-BE21EE2A1016Q35540129-3BB60E7C-169B-4DAC-B71F-826063965B38Q35879430-45895EB7-0FEA-4D39-9370-1360FE7F52D4Q35906126-7A060D71-CB13-44DC-BC33-34E041337EDAQ35970049-CE0B6EF5-5AC8-452B-8282-95BAC933AF5E
P2860
A hypervariable 130-kilobase genomic region of Magnetospirillum gryphiswaldense comprises a magnetosome island which undergoes frequent rearrangements during stationary growth.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
A hypervariable 130-kilobase g ...... ents during stationary growth.
@en
A hypervariable 130-kilobase g ...... ents during stationary growth.
@nl
type
label
A hypervariable 130-kilobase g ...... ents during stationary growth.
@en
A hypervariable 130-kilobase g ...... ents during stationary growth.
@nl
prefLabel
A hypervariable 130-kilobase g ...... ents during stationary growth.
@en
A hypervariable 130-kilobase g ...... ents during stationary growth.
@nl
P2093
P2860
P1476
A hypervariable 130-kilobase g ...... ents during stationary growth.
@en
P2093
Michael Kube
Sabrina Schübbe
Susanne Ullrich
P2860
P304
P356
10.1128/JB.187.21.7176-7184.2005
P407
P577
2005-11-01T00:00:00Z