Helical transformations of Salmonella flagella in vitro.
about
Structure of the bacterial flagellar protofilament and implications for a switch for supercoilingFilaments from Ignicoccus hospitalis show diversity of packing in proteins containing N-terminal type IV pilin helices.Archaeal flagellin combines a bacterial type IV pilin domain with an Ig-like domainDivergence of quaternary structures among bacterial flagellar filaments.Switch interactions control energy frustration and multiple flagellar filament structures.Key amino acid residues involved in the transitions of L- to R-type protofilaments of the Salmonella flagellar filamentLinkage map of Salmonella typhimurium, edition VVisualization of Flagella during bacterial SwarmingHelices.Flagellar filament structure and cell motility of Salmonella typhimurium mutants lacking part of the outer domain of flagellin.Force-extension measurements on bacterial flagella: triggering polymorphic transformations.Bacterial motility and chemotaxis: the molecular biology of a behavioral system.Inversion of a behavioral response in bacterial chemotaxis: explanation at the molecular level.Morphology-controlled synthesis of silica nanotubes through pH- and sequence-responsive morphological change of bacterial flagellar biotemplates.Unidirectional, intermittent rotation of the flagellum of Rhodobacter sphaeroides.Axial filament involvement in the motility of Leptospira interrogans.Waveform analysis and structure of flagella and basal complexes from Bdellovibrio bacteriovorus 109J.Isolation and characterization of motile Escherichia coli mutants resistant to bacteriophage chi.Bacterial flagella are firmly anchored.Development of flagella bio-templated nanomaterials for electronics.Supramolecular cellular filament systems: how and why do they form?Modeling polymorphic transformation of rotating bacterial flagella in a viscous fluid.Correlation between supercoiling and conformational motions of the bacterial flagellar filament.The flagellar filament of Rhodobacter sphaeroides: pH-induced polymorphic transitions and analysis of the fliC geneBiophysics of flagellar motility.The unidirectional flagellar motor of Rhodobacter sphaeroides WS8 can rotate either clockwise or counterclockwise: characterization of the flagellum under both conditions by antibody decoration.In vitro polymerization of flagellin excreted by a short-flagellum Salmonella typhimurium mutant.Passive rotation of flagella on paralyzed Salmonella typhimurium (mot) mutants by external rotatory driving force.Quasi- and nonequivalence in the structure of bacterial flagellar filament.A "mechanistic" explanation of the multiple helical forms adopted by bacterial flagellar filamentsA structural model of flagellar filament switching across multiple bacterial species.Bacteria-inspired nanorobots with flagellar polymorphic transformations and bundling.Bacterial flagellar axial structure and its construction.Molecular dynamics simulation of bacterial flagella.The effect of sugars on the morphology of the bacterial flagellum.Domain structure of flagellin.Mechanically tough, elastic and stable rope-like double nanohelices.Model for polymorphic transitions in bacterial flagella.Fluid-mechanical interaction of flexible bacterial flagella by the immersed boundary method.Continuum model for polymorphism of bacterial flagella.
P2860
Q27630815-A942E2DE-A055-40FB-90CA-9CD08A049DDAQ27679443-2A82E4BB-D303-43F1-A9E7-BD7F85E9AB81Q30276030-08761147-9C4F-4426-A570-19571098AAE2Q30446018-C34597A4-412D-4E35-AAA8-0ED64819F1E0Q30477255-E07E1FE9-99F8-4B50-86C3-9107BC133CB0Q30543770-7786DC1A-E8FA-461F-A9CC-D32E5728B128Q33622675-F633DD80-25AC-4570-B09E-04310D576704Q33964285-EEA744F5-F9EB-4A16-94FB-C2A444253F11Q34686925-B0D65642-EFBD-4C94-983C-C4D88CCB90C2Q35579851-A957897E-2311-4D94-AE38-701F0AC38CF3Q35774488-AA414DBA-6CC9-4AEF-B472-88C5E613B863Q35842910-1E8E8154-E79E-4177-A3E7-F7410791A9CBQ35989256-D251B91F-2ABC-4015-96B0-CE32825FACFCQ36132060-DBE666D6-4D6C-4DEB-9215-F0AA6C3C6BF1Q36227864-D882B969-BB09-4E03-9CB4-9EAC453CE350Q36338836-8261CAFF-87D9-4CC0-AD15-3FD7E4EC95B2Q36365937-20AE59A0-2999-4E18-9410-7AD7DF0BA7B5Q36421151-8DA4DD44-5B66-47BB-80E1-DE11F13C3717Q36994429-CDD1FA3E-4B7A-4773-8307-79B57375DE44Q37610308-547F29E0-5240-420D-9643-39AD27C1EFEBQ37974611-FEC77078-21E5-4DFB-B90B-D01541DCE83CQ38678655-808D1AA0-8A53-435C-BEC6-93E56A91498EQ39305469-F73A37ED-7EF1-421B-9A47-F5626917CD67Q39500733-30316EA4-DEFC-4EC6-967F-2FB61E34DC71Q39810492-C363BD9E-6F69-4E43-B0E0-EFC6FF2987E7Q39937034-399DB722-3850-4F1B-A42D-2696A05F5DD8Q39969357-4B4CF0B8-1D1A-43A0-87B5-265AC9EA8E61Q39974573-988926B8-2332-4F8E-9D3B-868B765D849DQ40114446-E07D001C-82BA-402A-AB56-A248B3FEB9D6Q41611818-829FE1EF-26AB-48D5-8F45-DAF00538E78FQ42378834-1A03A57A-78A3-4ECC-8CAB-EF2EC9C02154Q42620586-D9AA8144-D744-47E6-9E9A-D214906A7212Q47299483-45082F13-81A2-4BE9-A1FC-1AF764EFA25EQ47357374-757A75C9-D75D-4186-A1F0-F4297B8442D5Q50157255-CCCB7B3B-C4E5-4D71-890B-2A4C620ACB4BQ50208125-0371E12E-2E24-47DC-BC26-8952DCC420E3Q51091356-A52B0583-5A61-4466-9A7C-6F504D090F14Q51268963-F5C0D6E5-13E3-4B79-8131-BBAB78D5BE81Q51368040-32841C4E-CC07-491A-9250-EB7737592B99Q51374435-7D3A5134-556F-4F3D-B127-8446F8573B56
P2860
Helical transformations of Salmonella flagella in vitro.
description
1976 nî lūn-bûn
@nan
1976年の論文
@ja
1976年論文
@yue
1976年論文
@zh-hant
1976年論文
@zh-hk
1976年論文
@zh-mo
1976年論文
@zh-tw
1976年论文
@wuu
1976年论文
@zh
1976年论文
@zh-cn
name
Helical transformations of Salmonella flagella in vitro.
@en
Helical transformations of Salmonella flagella in vitro.
@nl
type
label
Helical transformations of Salmonella flagella in vitro.
@en
Helical transformations of Salmonella flagella in vitro.
@nl
prefLabel
Helical transformations of Salmonella flagella in vitro.
@en
Helical transformations of Salmonella flagella in vitro.
@nl
P1476
Helical transformations of Salmonella flagella in vitro.
@en
P2093
P304
P356
10.1016/0022-2836(76)90306-5
P407
P577
1976-09-01T00:00:00Z