Subunit architecture of intact protein complexes from mass spectrometry and homology modeling.
about
Mass spectrometry reveals modularity and a complete subunit interaction map of the eukaryotic translation factor eIF3Ion mobility-mass spectrometry for structural proteomicsChemical cross-linking and native mass spectrometry: A fruitful combination for structural biologyStructure of Rpn10 and Its Interactions with Polyubiquitin Chains and the Proteasome Subunit Rpn12eIF2B is a decameric guanine nucleotide exchange factor with a γ2ε2 tetrameric core.Identifying and Visualizing Macromolecular Flexibility in Structural BiologyIsoforms of U1-70k control subunit dynamics in the human spliceosomal U1 snRNPCrosslinking constraints and computational models as complementary tools in modeling the extracellular domain of the glycine receptorMolecular simulation-based structural prediction of protein complexes in mass spectrometry: the human insulin dimerMass spectrometry coupled experiments and protein structure modeling methods.Robotically assisted titration coupled to ion mobility-mass spectrometry reveals the interface structures and analysis parameters critical for multiprotein topology mappingProtein Structural Studies by Traveling Wave Ion Mobility Spectrometry: A Critical Look at Electrospray Sources and Calibration Issues.Revealing Higher Order Protein Structure Using Mass Spectrometry.Bound anions differentially stabilize multiprotein complexes in the absence of bulk solvent.Integrating mass spectrometry of intact protein complexes into structural proteomicsIntegrative structure modeling of macromolecular assemblies from proteomics dataIntegrating ion mobility mass spectrometry with molecular modelling to determine the architecture of multiprotein complexesNative MS: an 'ESI' way to support structure- and fragment-based drug discovery.Norwalk virus assembly and stability monitored by mass spectrometry.Biochemistry. Structural MS pulls its weight.Analysis of a soluble (UreD:UreF:UreG)2 accessory protein complex and its interactions with Klebsiella aerogenes urease by mass spectrometry.Architecture and dynamics of an A-kinase anchoring protein 79 (AKAP79) signaling complexTopological models of heteromeric protein assemblies from mass spectrometry: application to the yeast eIF3:eIF5 complexJoining forces: integrating proteomics and cross-linking with the mass spectrometry of intact complexes.Elucidating the higher-order structure of biopolymers by structural probing and mass spectrometry: MS3DNoncovalent protein tetramers and pentamers with "n" charges yield monomers with n/4 and n/5 chargesStructure and location of the regulatory β subunits in the (αβγδ)4 phosphorylase kinase complex.Mass spectrometry reveals differences in stability and subunit interactions between activated and nonactivated conformers of the (αβγδ)4 phosphorylase kinase complex.The potential impact of recent developments in three-dimensional quantitative interaction proteomics on structural biology.Correct charge state assignment of native electrospray spectra of protein complexes.Ion Mobility-Mass Spectrometry Analysis of Cross-Linked Intact Multiprotein Complexes: Enhanced Gas-Phase Stabilities and Altered Dissociation Pathways.The ubiquitin proteasome system in Caenorhabditis elegans and its regulation.Modeling protein assemblies in the proteome.Structural model and spectroscopic characteristics of the FMO antenna protein from the aerobic chlorophototroph, Candidatus Chloracidobacterium thermophilumIon mobility mass spectrometry of proteins and protein assemblies.Protein-nucleic acid complexes and the role of mass spectrometry in their structure determination.Finding the right balance: a personal journey from individual proteins to membrane-embedded motors: based on a lecture delivered at the 36th FEBS Congress in Torino, Italy, June 2011.Two decades of studying non-covalent biomolecular assemblies by means of electrospray ionization mass spectrometry.Assembling the pieces of macromolecular complexes: Hybrid structural biology approaches.Determining the topology of virus assembly intermediates using ion mobility spectrometry-mass spectrometry
P2860
Q24309617-A710F154-E051-4B65-9D35-1A6864A5857FQ26826931-FE581B50-00CD-460F-A9D0-1EFD32A445EBQ27007533-6E87B091-0074-4B2D-83FF-030B22328385Q27664179-85B31794-29A2-4F3C-A287-EE076C85E18AQ27933768-8B26EA2E-21DA-4417-96A7-B40D0506326BQ28077281-525570D2-6B34-4C77-AB6B-7259E73C388DQ28476244-CE8505CE-8C50-4717-8E38-4A40A635A3C3Q28540773-8516A41A-3D85-4335-8B55-6A02DD9A67D7Q28655834-A69831DA-E550-4600-8E88-5B1DEB87E438Q30354609-804A9BFC-9FDC-46F0-A951-141D81CC944DQ30354958-7206348B-0BC3-4BA5-8832-04E11C20A382Q30379165-100CFB65-0B42-439A-987F-78175A653782Q30386904-FD59EE33-0790-41A7-8412-09D5F121BBECQ30403879-B43CEA0D-2554-4821-BEB1-8151F412CDDCQ30417001-36C8DEB2-C126-4A89-8671-485DF694A53CQ33589651-83DE5263-A008-41F5-8578-609ABB68636EQ33658957-E9D73750-1BF7-4C26-AF10-832DCEE3FCA3Q33852381-D5B5DCD5-BECE-4E1F-BECA-6FDEA9048003Q34121907-33A70FAE-DBBF-4779-919C-AF3568AE36ACQ34652425-B6D20846-00CB-4228-A0C1-194DBF1EEE84Q34782283-B8A34937-B69E-46D4-A0EC-C7C04E0914DCQ34836322-17F60EED-6079-4DD8-815C-A026566EF85FQ35013562-A430118E-AB43-4EEA-BCA8-1EBEC860F077Q35863308-1D58E7AE-9EFC-40B6-BC6A-7DDDF1027DB9Q36205577-D5F431E5-D3FD-405D-8DEB-3AE19D54BF7EQ36335649-0FAD01DB-739F-4FC5-907B-9FB8B58B308EQ36347627-E85C7580-7500-445E-88E4-1DC750B1B8B4Q36455657-E83BB7B2-DA88-4B0D-9702-14CDD9E5897FQ37078577-1922A177-EDAF-422F-ABE2-2FF9C56BD487Q37401711-1BCEE278-AA7C-4E5A-8921-67552A9D984DQ37511997-BD4DBD6F-536E-434E-8BB4-5761DD62D659Q37587829-8B195DF6-758A-4444-BC3D-32E825612A02Q37623649-18F03ABD-6F6C-4171-B916-17382B66075FQ37627199-85851CDD-0981-45C7-B45E-19966E0FCAD6Q37737098-017214E8-29E1-4B96-B2B4-63A7A905B101Q37854594-04C08056-7846-435E-88FE-1F7566799979Q37970488-7B64C299-70D0-4616-B7B8-FBBCAF3D18C1Q37982686-BCB47217-EDF8-49E8-B74F-FE536C758494Q38371374-C65B7FAF-57C6-4C6B-86E3-724862CAAFE7Q38963582-5664AA73-BA61-48F4-AFB8-CA3421EBDDAC
P2860
Subunit architecture of intact protein complexes from mass spectrometry and homology modeling.
description
2008 nî lūn-bûn
@nan
2008 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի մարտին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
Subunit architecture of intact ...... rometry and homology modeling.
@ast
Subunit architecture of intact ...... rometry and homology modeling.
@en
Subunit architecture of intact ...... rometry and homology modeling.
@nl
type
label
Subunit architecture of intact ...... rometry and homology modeling.
@ast
Subunit architecture of intact ...... rometry and homology modeling.
@en
Subunit architecture of intact ...... rometry and homology modeling.
@nl
prefLabel
Subunit architecture of intact ...... rometry and homology modeling.
@ast
Subunit architecture of intact ...... rometry and homology modeling.
@en
Subunit architecture of intact ...... rometry and homology modeling.
@nl
P50
P356
P1476
Subunit architecture of intact ...... trometry and homology modeling
@en
P2093
Helena Hernández
Thomas Taverner
P304
P356
10.1021/AR700218Q
P407
P50
P577
2008-03-04T00:00:00Z