about
A mutational analysis of the interaction between FliG and FliM, two components of the flagellar motor of Escherichia coliSize structures sensory hierarchy in ocean lifeUncoupled phosphorylation and activation in bacterial chemotaxis. The 2.1-A structure of a threonine to isoleucine mutant at position 87 of CheYOptimal noise filtering in the chemotactic response of Escherichia coliChemotaxis of bacteria in glass capillary arrays. Escherichia coli, motility, microchannel plate, and light scatteringChemotactic patterns without chemotaxis.Excitatory signaling in bacterial probed by caged chemoeffectorsPhysical mechanisms for chemotactic pattern formation by bacteria.Response kinetics of tethered Rhodobacter sphaeroides to changes in light intensity.Migration of bacteria in semisolid agarRole of CheW protein in coupling membrane receptors to the intracellular signaling system of bacterial chemotaxis.Highly designable phenotypes and mutational buffers emerge from a systematic mapping between network topology and dynamic outputChemotaxis: signalling modules join hands at front and tail.Bound attractant at the leading vs. the trailing edge determines chemotactic prowess.A diffusion gradient chamber for studying microbial behavior and separating microorganismsMutations in the two flagellin genes of Rhizobium meliloti.Symmetries in bacterial motilityChemotaxis in a gliding bacterium.Computation of mutual fitness by competing bacteria.Experimental and theoretical bases of specific affinity, a cytoarchitecture-based formulation of nutrient collection proposed to supercede the Michaelis-Menten paradigm of microbial kinetics.How to understand and outwit adaptationSensitivity increase in the photophobic response of Halobacterium halobium reconstituted with retinal analogs: a novel interpretation for the fluence-response relationship and a kinetic modeling.Quantitative studies of bacterial chemotaxis and microbial population dynamics.What do molecules do when we are not looking? State sequence analysis for stochastic chemical systems.Chemotaxis and chemokinesis in eukaryotic cells: the Keller-Segel equations as an approximation to a detailed model.
P2860
Q24684582-9B67F9A7-3EFB-43F8-941C-6D44D110B387Q26786003-E175E1C0-E28A-427D-AFA5-80DA6DD0E0AFQ27729774-CD12D976-37C6-4136-954F-AF0377A3789FQ28469071-B7DED703-870D-49DB-B742-92380B96D798Q31054313-33D12576-BB99-499F-AC70-61E1B33C4AF3Q33977696-E155CC55-B727-47B4-B900-6FD4493BE444Q34020156-E0F0236F-7AB5-4763-BDC6-3352C922F0BEQ34167516-41A71F74-95C7-4C66-8BC3-84F531FF1365Q34172565-1D740F75-8A41-4FD7-AEC1-D96670F07A3BQ34303426-50174E79-0B69-4EAF-A086-DE224A42F744Q34318420-FB781AD4-5C87-4311-8750-D1CC2AB10F7BQ34573018-CFBC7964-D443-40FC-AC0C-ADCF26E10A87Q35622428-6A08214B-558E-494F-B7C8-5C69AEEDE728Q35925602-3A4E60FD-5B82-4532-B39E-EE52257AB642Q36054464-D7057677-AE77-4347-B34C-4303AD3042E7Q36146989-C3F5FDAB-E617-497C-A649-D53E706C1B28Q36246009-66640F39-6605-4374-952C-A5C4EF585FA2Q36327272-E5154DC1-ACA7-4061-AFFC-CDF013D0D3C5Q37011224-7F6E277A-D69A-4C4B-9F0E-CE66F639FACEQ37552996-58CDD0FE-C674-4E82-8FBD-4587CA2BDE0AQ39331090-D94DC251-0599-40E4-BB38-301286E14C3FQ41107304-90DC67A9-8A79-4B84-B4CA-864F5D1FE3EFQ41136421-E73C9C7F-AFE0-4113-8466-63B52A854548Q41848338-3E8FEC78-C122-4608-997B-3FB53B9FA961Q52385063-4838D7F5-1CD1-49CD-9C93-08A56B4F6C6D
P2860
description
1988 nî lūn-bûn
@nan
1988年の論文
@ja
1988年学术文章
@wuu
1988年学术文章
@zh-cn
1988年学术文章
@zh-hans
1988年学术文章
@zh-my
1988年学术文章
@zh-sg
1988年學術文章
@yue
1988年學術文章
@zh
1988年學術文章
@zh-hant
name
A physicist looks at bacterial chemotaxis.
@en
type
label
A physicist looks at bacterial chemotaxis.
@en
prefLabel
A physicist looks at bacterial chemotaxis.
@en
P1476
A physicist looks at bacterial chemotaxis.
@en
P2093
P356
10.1101/SQB.1988.053.01.003
P478
P577
1988-01-01T00:00:00Z