Use of site-directed cysteine and disulfide chemistry to probe protein structure and dynamics: applications to soluble and transmembrane receptors of bacterial chemotaxis.
about
Functional Analysis of the Transmembrane Domain in Paramyxovirus F Protein-Mediated Membrane FusionHydrophobic Core Flexibility Modulates Enzyme Activity in HIV-1 ProteaseLigand-induced movements of inner transmembrane helices of Glut1 revealed by chemical cross-linking of di-cysteine mutantsAssembly of the transmembrane domain of E. coli PhoQ histidine kinase: implications for signal transduction from molecular simulationsAmino terminal domains of the NMDA receptor are organized as local heterodimersDefining a key receptor-CheA kinase contact and elucidating its function in the membrane-bound bacterial chemosensory array: a disulfide mapping and TAM-IDS Study.Crystal structure of BamB bound to a periplasmic domain fragment of BamA, the central component of the β-barrel assembly machineThe cavity-chaperone Skp protects its substrate from aggregation but allows independent folding of substrate domainsMolecular motions involved in Na-K-Cl cotransporter-mediated ion transport and transporter activation revealed by internal cross-linking between transmembrane domains 10 and 11/12.Cysteine-free proteins in the immunobiology of arthropod-borne diseases.Coincidence detection and bi-directional transmembrane signaling control a bacterial second messenger receptor.The Hin recombinase assembles a tetrameric protein swivel that exchanges DNA strands.Thermal domain motions of CheA kinase in solution: Disulfide trapping reveals the motional constraints leading to trans-autophosphorylationStructure of the ternary complex formed by a chemotaxis receptor signaling domain, the CheA histidine kinase, and the coupling protein CheW as determined by pulsed dipolar ESR spectroscopy.Kinase-active signaling complexes of bacterial chemoreceptors do not contain proposed receptor-receptor contacts observed in crystal structuresGABA(A) receptor transmembrane amino acids are critical for alcohol action: disulfide cross-linking and alkyl methanethiosulfonate labeling reveal relative location of binding sitesRole of the F1 region in the Escherichia coli aerotaxis receptor AerDisulphide trapping of the GABA(A) receptor reveals the importance of the coupling interface in the action of benzodiazepines.Transient oligomerization of the SARS-CoV N protein--implication for virus ribonucleoprotein packaging.Demonstration of physical proximity between the N terminus and the S4-S5 linker of the human ether-a-go-go-related gene (hERG) potassium channelFunctional expression of human NKCC1 from a synthetic cassette-based cDNA: introduction of extracellular epitope tags and removal of cysteines.Assembly states of FliM and FliG within the flagellar switch complex.Different conformations of the kinase-on and kinase-off signaling states in the Aer HAMP domain.Self-association of the histidine kinase CheA as studied by pulsed dipolar ESR spectroscopy.Transmembrane signaling in the sensor kinase DcuS of Escherichia coli: A long-range piston-type displacement of transmembrane helix 2Conformational Transitions that Enable Histidine Kinase Autophosphorylation and Receptor Array Integration.Determination of the physiological dimer interface of the PhoQ sensor domain.Multiple approaches converge on the structure of the integrin alphaIIb/beta3 transmembrane heterodimer.Delineating PAS-HAMP interaction surfaces and signalling-associated changes in the aerotaxis receptor AerIntra-subunit flexibility underlies activation and allosteric modulation of neuronal nicotinic acetylcholine receptors.Intermolecular disulfide bond to modulate protein function as a redox-sensing switch.Functional architecture of the CFTR chloride channel.The enigmatic cytoplasmic regions of KCNH channels.The Interaction between the Third Type III Domain from Fibronectin and Anastellin Involves β-Strand Exchange.Interaction between 2 extracellular loops influences the activity of the cystic fibrosis transmembrane conductance regulator chloride channel.Type IV Pilus Alignment Subcomplex Proteins PilN and PilO Form Homo- and Heterodimers in Vivo.HAMP Domain Rotation and Tilting Movements Associated with Signal Transduction in the PhoQ Sensor KinaseThe structure of a receptor with two associating transmembrane domains on the cell surface: integrin alphaIIbbeta3.Structure, function, and on-off switching of a core unit contact between CheA kinase and CheW adaptor protein in the bacterial chemosensory array: A disulfide mapping and mutagenesis studySite-specific protein cross-linking with genetically incorporated 3,4-dihydroxy-L-phenylalanine.
P2860
Q27489741-50E056DC-BDED-4DD0-9166-74C4B7D5408DQ27676981-8C08FAAD-643B-471E-8182-67BAF29F127EQ28480951-E8DDE8BC-B1FC-4AEE-B7E1-7B5AAAC08361Q28485272-8D266B38-34C9-4284-A01D-DDAB376279A2Q28571825-ED11F50D-6C6C-4A3A-AA11-84C5ECD6CFD3Q30009859-FA9F1D70-442E-476C-9C86-84B7308CF033Q30153283-AAC805BD-2966-4021-A640-0AF6B60E1C48Q30157376-759165BC-9B5A-4BE8-8ADB-D1CA0003C021Q30358170-BBF46772-AF09-4A38-AB6B-9E92D4A0C527Q30384324-14FFFBA3-0654-4E14-A20C-FED361F0AC05Q30396694-00AD9EE5-0C8D-48B9-B625-0D1FA5A106FEQ30489423-26E5C1C1-ECB5-4DB9-B508-CD768E9CE71AQ33414216-51565F26-3A8A-428B-9439-0E2F738BED74Q34107640-E9656DB0-D4B4-4305-9876-14718565B84EQ34117183-517F9DD7-270C-4D2E-9820-20BAD6534A68Q34294062-B4A7A720-F41F-4F60-9C86-D46A54E69FA0Q34484264-4A18651C-C929-4C9F-9340-796BBF0B2515Q34583562-77DA98ED-F31C-410A-99C9-C0C3D7557F52Q34746639-EBA3642B-5EB9-4FC0-984D-0BD91EA294DCQ34998277-74614171-15CB-46A0-A912-AE3909F84839Q35067684-76EF2ECB-D6F5-4F4B-A274-A542406C7D83Q35071230-5873F32D-6D51-4C6F-9ABA-5218A05228C8Q35139646-22D8BD22-520E-4B7B-9A0A-CEF4C47BA474Q35926190-3235438D-FB01-406E-A325-F2E5D8E96220Q36055415-500AB5C4-BF9C-42DA-B91C-523AA96C2C61Q36486040-F56BC182-4204-493F-917B-752A2EC6A8FAQ36890483-FF210E25-9E5E-49C2-A958-B42410555E95Q37377101-438449D0-0E19-436A-B227-FAF18516760AQ37503508-D361416E-D0AA-464C-9F26-77A1EB6A68B3Q37674639-8FB83393-8C23-4CFD-9869-207E9F972652Q37697032-7BAC5D36-4BBF-4EAF-BD5C-71187D3BD250Q38171539-876A3D8D-8CCC-4FE7-AE81-7F4DFB12C50FQ38243381-E50419E4-630A-4C70-BD09-76E866ECDEC7Q38618635-CEC6CDA5-C281-4449-B856-05640A25A13FQ38953529-5303CC8B-8EF0-4506-87D5-F22AB07D5F80Q39543206-6E0D096D-1BD2-4F59-B15D-98B9F4D6A929Q40898487-11188E46-F61C-4402-A4D4-659EE4DF0F5BQ41543290-4CF64293-24C9-49BC-8D5A-E2FD69ABD27DQ41888519-211477E1-A0E9-4893-B3F2-A4FB9028FB7EQ41910095-DF90C060-1C00-4B75-BD47-8B575CF3CBAD
P2860
Use of site-directed cysteine and disulfide chemistry to probe protein structure and dynamics: applications to soluble and transmembrane receptors of bacterial chemotaxis.
description
2007 nî lūn-bûn
@nan
2007 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@ast
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@en
type
label
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@ast
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@en
prefLabel
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@ast
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@en
P2093
P2860
P1476
Use of site-directed cysteine ...... ptors of bacterial chemotaxis.
@en
P2093
Joseph J Falke
Randal B Bass
Scott L Butler
Stephen A Chervitz
Susan L Gloor
P2860
P356
10.1016/S0076-6879(07)23002-2
P407
P577
2007-01-01T00:00:00Z