about
Bioenergetics of the Archaea.An Element of Determinism in a Stochastic Flagellar Motor SwitchCrystal structures of CheY mutants Y106W and T87I/Y106W. CheY activation correlates with movement of residue 106Changing cellular location of CheZ predicted by molecular simulationsGenome sequence of the pathogenic intestinal spirochete brachyspira hyodysenteriae reveals adaptations to its lifestyle in the porcine large intestine.Computer-aided resolution of an experimental paradox in bacterial chemotaxis.The two-component signaling pathway of bacterial chemotaxis: a molecular view of signal transduction by receptors, kinases, and adaptation enzymesExcitatory signaling in bacterial probed by caged chemoeffectorsTemperature-induced switching of the bacterial flagellar motorHow signals are heard during bacterial chemotaxis: protein-protein interactions in sensory signal propagation.Origins of individual swimming behavior in bacteria.Chemotactic responses of Escherichia coli to small jumps of photoreleased L-aspartateComputer simulation of the phosphorylation cascade controlling bacterial chemotaxisFliG and FliM distribution in the Salmonella typhimurium cell and flagellar basal bodies.Tyrosine 106 of CheY plays an important role in chemotaxis signal transduction in Escherichia coli.Control of direction of flagellar rotation in bacterial chemotaxis.Acetylation at Lys-92 enhances signaling by the chemotaxis response regulator protein CheY.The carboxy-terminal portion of the CheA kinase mediates regulation of autophosphorylation by transducer and CheW.New structural features of the flagellar base in Salmonella typhimurium revealed by rapid-freeze electron microscopy.Phosphorylation-dependent binding of a signal molecule to the flagellar switch of bacteriaA model of excitation and adaptation in bacterial chemotaxis.Bacterial tethering analysis reveals a "run-reverse-turn" mechanism for Pseudomonas species motilityA model of excitation and adaptation in bacterial chemotaxis.A chemotactic signaling surface on CheY defined by suppressors of flagellar switch mutations.Rotation and switching of the flagellar motor assembly in Halobacterium halobium.Computer analysis of the binding reactions leading to a transmembrane receptor-linked multiprotein complex involved in bacterial chemotaxis.Chemotaxis and phototaxis require a CheA histidine kinase in the archaeon Halobacterium salinarium.Binding of the chemotaxis response regulator CheY to the isolated, intact switch complex of the bacterial flagellar motor: lack of cooperativity.Torque and switching in the bacterial flagellar motor. An electrostatic model.Response regulator output in bacterial chemotaxis.Acetylation of the response regulator, CheY, is involved in bacterial chemotaxis.Receptor methylation controls the magnitude of stimulus-response coupling in bacterial chemotaxis.Hidden stochastic nature of a single bacterial motor.
P2860
Q24516903-70F2D933-5EB0-4C2F-8769-18BE6B038178Q27348660-7E797737-1203-4931-ABE3-D8D8089669D4Q27734752-9DA2BA18-5F19-4772-97D2-900B0FDBB609Q33242803-41A88AEB-8F83-4BF3-BF92-9D577C82BD30Q33415025-C0387110-DB08-4CA6-9474-5E99178E61D3Q33734284-256DACA6-70F3-4521-A962-A84E9A210E39Q33973438-8E725CEB-3F47-442E-AB8F-8AEB96CC91BBQ34020156-0AAD0610-2865-4062-A210-F1E079FA008BQ34040868-5058EB96-E9C0-4654-9AD5-16594D782687Q34090837-A77719F2-080B-4497-A7B9-A1C1EF2C6D94Q34167054-8FF152DB-A047-45D7-A265-2EA014CC30FBQ34170096-CA5E0271-A165-4807-BE7F-602A8B6C1DB1Q34436874-96D1B0A3-BACA-4410-80F9-3E2490198E46Q35600631-10AE636F-6154-45E1-B50E-AD500239AE1CQ35609743-D13E44C3-0FD2-4DD5-84AF-6DCAB27B42EEQ35671887-692CB291-0116-4100-A920-092EBC8077A9Q36059913-0DE9472C-7A63-4F13-9572-C575E0B776EAQ36094633-419873EA-06BC-46EC-AF97-BC19BD88C07CQ36145829-1069336D-19C9-4AC9-98CD-A5D3096A444FQ36553581-66B218B6-6CD9-43FC-85FA-CB13B964C5D0Q36654301-66AB30F6-B4F4-44FE-B4D1-D89ECDC456A8Q37035852-7ACE6C1B-FA92-4C1C-87D6-D4031D1044F9Q39651626-6293D06E-6A20-472A-97A3-132A70006C9EQ39940781-3769B599-5F0C-4EC4-AF8D-2DD9DEB08E41Q39940913-F9DE8F58-C9ED-4FAA-B911-6A402FE4FFFBQ40367116-0477DC23-2369-47D0-9658-1742655441CFQ40805752-F6C8FC6F-FB4D-48DD-B332-6E2BAC480895Q42440861-0663B395-B99D-4AC1-AC28-26425E24D20FQ42584169-C2F358B5-5A23-4B0E-B0BE-2236B42F3130Q42649639-05BC490C-0737-49EE-BE90-99E8B996E6C3Q43612719-ADCB784B-2E0F-40D5-A8AE-78E491F72C35Q44064998-19E7FDF7-13C9-44C1-AECA-E523B0B50044Q53603506-A51BE703-42EB-4EBF-8EBE-BC9E74767D30
P2860
description
1989 nî lūn-bûn
@nan
1989年の論文
@ja
1989年論文
@yue
1989年論文
@zh-hant
1989年論文
@zh-hk
1989年論文
@zh-mo
1989年論文
@zh-tw
1989年论文
@wuu
1989年论文
@zh
1989年论文
@zh-cn
name
Multiple kinetic states for the flagellar motor switch.
@ast
Multiple kinetic states for the flagellar motor switch.
@en
type
label
Multiple kinetic states for the flagellar motor switch.
@ast
Multiple kinetic states for the flagellar motor switch.
@en
prefLabel
Multiple kinetic states for the flagellar motor switch.
@ast
Multiple kinetic states for the flagellar motor switch.
@en
P2860
P1476
Multiple kinetic states for the flagellar motor switch.
@en
P2093
P2860
P304
P356
10.1128/JB.171.11.6279-6287.1989
P407
P577
1989-11-01T00:00:00Z