Electrostatic stabilization of a native protein structure in the gas phase
about
Native Mass Spectrometry in Fragment-Based Drug DiscoveryIon Activation Methods for Peptides and ProteinsProteins with highly similar native folds can show vastly dissimilar folding behavior when desolvated.Structural significance of the β1K396 residue found in the Porphyromonas gingivalis sialidase β-propeller domain: a computational study with implications for novel therapeutics against periodontal disease.Probing Protein Structure and Folding in the Gas Phase by Electron Capture DissociationNew developments in protein structure-function analysis by MS and use of hydrogen-deuterium exchange microfluidics.Repeatability and reproducibility of product ion abundances in electron capture dissociation mass spectrometry of peptides.Top-down mass spectrometry for the analysis of combinatorial post-translational modifications.Principles of electron capture and transfer dissociation mass spectrometry applied to peptide and protein structure analysis.Fragmentation of integral membrane proteins in the gas phase.The role of salt bridges, charge density, and subunit flexibility in determining disassembly routes of protein complexes.Probing the electron capture dissociation mass spectrometry of phosphopeptides with traveling wave ion mobility spectrometry and molecular dynamics simulations.Revealing ligand binding sites and quantifying subunit variants of noncovalent protein complexes in a single native top-down FTICR MS experimentHow ubiquitin unfolds after transfer into the gas phase.Electron-capture dissociation and ion mobility mass spectrometry for characterization of the hemoglobin protein assemblyLeveraging Electron Transfer Dissociation for Site Selective Radical Generation: Applications for Peptide Epimer Analysis.Probing Asymmetric Charge Partitioning of Protein Oligomers during Tandem Mass Spectrometry.Top-down mass spectrometry: recent developments, applications and perspectivesNative top-down mass spectrometry for the structural characterization of human hemoglobin.Salt Bridge Rearrangement (SaBRe) Explains the Dissociation Behavior of Noncovalent ComplexesNative MS and ECD Characterization of a Fab-Antigen Complex May Facilitate Crystallization for X-ray DiffractionCharge site mass spectra: conformation-sensitive components of the electron capture dissociation spectrum of a proteinNative Top-Down Mass Spectrometry of TAR RNA in Complexes with a Wild-Type tat Peptide for Binding Site Mapping.193 nm Ultraviolet Photodissociation Mass Spectrometry of Tetrameric Protein Complexes Provides Insight into Quaternary and Secondary Protein Topology.Electron capture dissociation and drift tube ion mobility-mass spectrometry coupled with site directed mutations provide insights into the conformational diversity of a metamorphic protein.Unfolding and Folding of the Three-Helix Bundle Protein KIX in the Absence of Solvent.Ion mobility-mass spectrometry reveals conformational flexibility in the deubiquitinating enzyme USP5.Microsecond pulsed hydrogen/deuterium exchange of electrosprayed ubiquitin ions stored in a linear ion trap.Ion mobility spectrometry-hydrogen deuterium exchange mass spectrometry of anions: part 1. Peptides to proteins.Determinants of gas-phase disassembly behavior in homodimeric protein complexes with related yet divergent structures.The pH Dependence of Product Ion Spectra Obtained from Precursor Ions with the Same Charge Number in ESI of Carbonic Anhydrase 2.Characterization of modified RNA by top-down mass spectrometry.Femtosecond laser vaporization that preserves protein-folded structure: an unproven ideaDoes Electron Capture Dissociation Cleave Protein Disulfide Bonds?Solution dependence of the collisional activation of ubiquitin [M + 7H](7+) ions.Radical additions to aromatic residues in peptides facilitate unexpected side chain and backbone losses.Cation-induced stabilization of protein complexes in the gas phase: mechanistic insights from hemoglobin dissociation studies.Interactions of Protonated Guanidine and Guanidine Derivatives with Multiply Deprotonated RNA Probed by Electrospray Ionization and Collisionally Activated Dissociation.Gas-Phase Protein Salt Bridge Stabilities from Collisional Activation and Electron Transfer Dissociation.Radical solutions: Principles and application of electron-based dissociation in mass spectrometry-based analysis of protein structure.
P2860
Q26740022-AC2E1168-2FA8-49BF-995F-87AEB7120AF6Q29391863-3843062D-4EC0-40C8-96C4-D0BF0ED05A14Q30355839-9CD1CF7A-ADCF-48F6-A33B-4A48CE3C8062Q30364436-C83F259C-103B-4DF0-A598-1979321CFFF1Q30373636-D6C32155-DC20-4B43-B78E-DF07FB14A41DQ30403735-FC553BB8-EBF2-4C01-99BF-8D6A5A4C44DFQ30408283-A15F012B-0736-4937-A7E6-F54F11A136A9Q30418309-1D871E98-C45C-47DD-98E0-CB30CECE96A0Q30427725-9E0D075B-E80D-4580-83EC-7004E71C641CQ33598813-48950CF9-005E-48A0-AF54-66984553D62DQ34357280-FD112485-48EC-4134-840B-156FCF50A1F5Q35578081-0D59D6D8-0EA9-4270-AB7F-04883B4E0238Q35647718-32FC5A9B-D98D-4997-9E04-822B825DB391Q35936223-D707C4BC-468B-456A-B2EB-F1849ED2DD9FQ35946012-3B6A4DF1-BE19-4F20-8E75-1BDAE3567E3AQ36333456-4FDF3BA3-BA2B-41A4-BE63-FF6CC286A1A9Q36357695-29E5E3B8-F56B-49D1-AB46-619C48AE9773Q36419886-382788DF-6713-43C2-B93D-C66749A06A4FQ36514662-D2D6F326-F6C6-4BC8-9864-E769D743BCB6Q36896722-3F906D3C-581F-4D32-90AC-33E12C486002Q36984104-8A1B943E-0837-4915-8DDB-D228E736210BQ37062379-B047663A-C3C0-432D-8DD7-551A5022C202Q39078803-D4FBEC62-956B-4F48-BFDC-5D401263DDEDQ41076155-584E4BD3-FC5B-4836-B7DB-BAB79F862DD9Q41169029-147261B2-CA33-4C0A-9C41-8960E3402BDBQ41396279-C69833FE-C063-4207-A958-65D4249E40CBQ41495509-33E6E564-7FA8-453C-904F-84E5971A25A3Q41632772-9EE8E01B-D44E-40D2-A3F9-363F04700D1AQ41686263-20EB651D-B1A0-45A8-8D43-D889F27319E2Q41980348-2A49A9DF-23A0-4A61-BFF3-BC9BC7837DF3Q42217884-012CB19C-E9DA-4D1D-A618-2DEEB800D24CQ42433484-B2CE9C18-2FFD-4BCC-9453-433724509B0CQ42690367-E25901A1-8F4E-416A-A843-FD4B744288EAQ42783119-21574DD1-515A-4880-8242-E288FFAD070CQ42909554-95B16932-17F8-4A11-B93D-39A20FF8B834Q46406420-3E9816BD-5911-42E9-891D-3A4C859F1383Q46942908-2406D797-48F6-48BD-AA3D-FF5A886693D0Q47158532-6E8C0470-7721-4B60-8E4F-CB67A7136837Q47619314-93D21975-4AAC-46CF-A081-51F69781130DQ50098486-B1FF7FEE-F507-4AF0-BF39-CDA17FC29130
P2860
Electrostatic stabilization of a native protein structure in the gas phase
description
2010 nî lūn-bûn
@nan
2010 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Electrostatic stabilization of a native protein structure in the gas phase
@ast
Electrostatic stabilization of a native protein structure in the gas phase
@en
type
label
Electrostatic stabilization of a native protein structure in the gas phase
@ast
Electrostatic stabilization of a native protein structure in the gas phase
@en
prefLabel
Electrostatic stabilization of a native protein structure in the gas phase
@ast
Electrostatic stabilization of a native protein structure in the gas phase
@en
P2093
P2860
P356
P1476
Electrostatic stabilization of a native protein structure in the gas phase
@en
P2093
Kathrin Breuker
Martin Tollinger
Sven Brüschweiler
P2860
P304
P356
10.1002/ANIE.201005112
P407
P577
2010-11-09T00:00:00Z