Prediction of peptide retention times in high-pressure liquid chromatography on the basis of amino acid composition.
about
Peptide orientation affects selectivity in ion-exchange chromatographyHydrophobicity of Antifungal β-Peptides Is Associated with Their Cytotoxic Effect on In Vitro Human Colon Caco-2 and Liver HepG2 CellsA subpopulation of estrogen receptors are modified by O-linked N-acetylglucosamineProtein unfolding during reversed-phase chromatography: I. Effect of surface properties and duration of adsorption.Protein unfolding during reversed-phase chromatography: II. Role of salt type and ionic strength.On the utility of predictive chromatography to complement mass spectrometry based intact protein identification.Phosphorylation and activation of epidermal growth factor receptors in cells transformed by the src oncogenePyteomics--a Python framework for exploratory data analysis and rapid software prototyping in proteomics.A statistical learning approach to the modeling of chromatographic retention of oligonucleotides incorporating sequence and secondary structure data.Generation of accurate peptide retention data for targeted and data independent quantitative LC-MS analysis: Chromatographic lessons in proteomics.Techniques for neuropeptide determination.Statistical learning of peptide retention behavior in chromatographic separations: a new kernel-based approach for computational proteomics.Protein abundance profiling of the Escherichia coli cytosolDetection of co-eluted peptides using database search methods.A robust linear regression based algorithm for automated evaluation of peptide identifications from shotgun proteomics by use of reversed-phase liquid chromatography retention time.LC-MSsim--a simulation software for liquid chromatography mass spectrometry dataThe distribution of CTL epitopes in HIV-1 appears to be random, and similar to that of other proteomes.emPAI Calc--for the estimation of protein abundance from large-scale identification data by liquid chromatography-tandem mass spectrometry.Structure and action of buccalin: a modulatory neuropeptide localized to an identified small cardioactive peptide-containing cholinergic motor neuron of Aplysia californica.Mutagenesis Objective Search and Selection Tool (MOSST): an algorithm to predict structure-function related mutations in proteins.Estimating the fitness cost of escape from HLA presentation in HIV-1 protease and reverse transcriptase.Proteomics based on high-efficiency capillary separations.Chemical and functional characterization of an altered form of ribosomal protein S4 derived from a strain of E. coli defective in auto-regulation of the alpha operon.Mapping hydrophobicity on the protein molecular surface at atom-level resolution.Hypothesis about the function of membrane-buried proline residues in transport proteinsRole of conformational changes in the elution of proteins from reversed-phase HPLC columnsPredicting retention time in hydrophilic interaction liquid chromatography mass spectrometry and its use for peak annotation in metabolomicsCentral delta-opioid receptor interactions and the inhibition of reflex urinary bladder contractions in the ratImproved peptide elution time prediction for reversed-phase liquid chromatography-MS by incorporating peptide sequence information.Advanced nanoscale separations and mass spectrometry for sensitive high-throughput proteomics.Processing of lysozyme by macrophages: identification of the determinant recognized by two T-cell hybridomas.Gonococcal pili. Primary structure and receptor binding domain.Site-specific glycosylation of the human cytomegalovirus tegument basic phosphoprotein (UL32) at serine 921 and serine 952Requirements for prediction of peptide retention time in reversed-phase high-performance liquid chromatography: hydrophilicity/hydrophobicity of side-chains at the N- and C-termini of peptides are dramatically affected by the end-groups and locationDetermination of intrinsic hydrophilicity/hydrophobicity of amino acid side chains in peptides in the absence of nearest-neighbor or conformational effects.Unambiguous determination of isobaric histone modifications by reversed-phase retention time and high-mass accuracy.Intrinsic amino acid side-chain hydrophilicity/hydrophobicity coefficients determined by reversed-phase high-performance liquid chromatography of model peptides: comparison with other hydrophilicity/hydrophobicity scales.Identification of a mutant human insulin predicted to contain a serine-for-phenylalanine substitutionPre-binding of small protein B to a stalled ribosome triggers trans-translation.Peptide retention time prediction.
P2860
Q24634607-06E5B676-8CD6-4D82-8FA5-DC4C2F468603Q28550897-299529F5-376F-4C6E-873E-8C2627E2C94EQ28590465-D62F6FAF-8602-4385-B4EF-E18BEA866D4CQ30308120-291DE91D-40A2-460F-B069-75F9B2A92323Q30308123-1DBAD254-19F8-48FD-A87D-74E6DF9F8F62Q30406856-3A1E354C-8E53-467A-8553-70FE6966FC8EQ30441810-41AB392C-21A7-4B68-BC68-3AF2783CA480Q30584760-3752B182-AED8-4F4B-B147-59E0C96FAEA0Q31115603-B58F8D7E-3D36-44C7-BAB3-59FDCCCF7730Q31134688-36540EB8-D86A-45FB-BFAE-A5ABEC5A7877Q33245828-7A246DB3-B21F-4424-92ED-3ED77FEDF950Q33308294-3A529B27-B1FB-4411-9711-AE65C49CA242Q33321436-6C9B5B82-7FBB-4255-81A4-01FC569788AEQ33348774-396FE357-8631-41CB-85E4-4EE9965AC48FQ33361481-DEEEC04B-4081-4BA0-AE8E-C2D246292A1AQ33374624-C73A0D79-6BF3-40ED-BC0E-2D82A40CC361Q33490243-F3C34E49-FEA5-4C19-964C-53237D967014Q33520630-8EAF7B0E-27FC-409C-B95D-57422F65FC31Q33641906-33668FCE-B567-4B7E-BB05-007BC96F58E1Q33882882-6A06F904-B990-4FF8-BA33-0D7C3AB347B5Q34288751-77B722F1-8D5F-4E3F-A92C-A522069A2DD7Q34896427-0D814941-4DCD-476A-8682-AC894E54B307Q35050969-95D1996E-A2BC-473A-A74C-C302C1403A0FQ35477277-A2CD0660-7D24-489C-94DC-3C335A79EAD7Q35590093-B43B0C2B-E791-4FD2-B45F-8F6837D2306DQ35610782-6980B99E-BF71-408A-B570-3D094334BBE8Q35631209-DC977AB2-4846-4474-88D4-C854BAB9191CQ35886352-67FA5A08-9C2C-44A3-B758-551D50F7E0D2Q35902162-211B937A-B41D-4C8C-A842-123684D459A3Q36184821-B573F5B4-F5C7-41C5-BEA0-0D1710B28D51Q36257785-651D144D-E90D-4315-910E-1BD99A944878Q36348735-6D0B37C0-EAC5-4A93-8F36-8EF6E06737DEQ36638228-CC4F32C6-D4B9-43AF-8920-0FB219CEC76DQ37292547-E0386678-15F2-47FC-8D22-1052DB34C5BCQ37348516-401DCEB5-84B0-40F8-B005-B62F5670C707Q37456238-51A5353D-B0D2-49C0-AF78-A61ED7C64E7FQ37473836-BBB123C4-3275-4E2B-BB12-48740D0C2D11Q37506718-B541D48E-146F-4271-937D-095EA4F92A40Q38342707-0B350F0E-9DA2-4129-903C-A23D089CB00AQ38707969-1A77CBC8-D582-4C01-9C86-74FD08BAA9A6
P2860
Prediction of peptide retention times in high-pressure liquid chromatography on the basis of amino acid composition.
description
1980 nî lūn-bûn
@nan
1980年の論文
@ja
1980年学术文章
@wuu
1980年学术文章
@zh-cn
1980年学术文章
@zh-hans
1980年学术文章
@zh-my
1980年学术文章
@zh-sg
1980年學術文章
@yue
1980年學術文章
@zh
1980年學術文章
@zh-hant
name
Prediction of peptide retentio ...... sis of amino acid composition.
@ast
Prediction of peptide retentio ...... sis of amino acid composition.
@en
type
label
Prediction of peptide retentio ...... sis of amino acid composition.
@ast
Prediction of peptide retentio ...... sis of amino acid composition.
@en
prefLabel
Prediction of peptide retentio ...... sis of amino acid composition.
@ast
Prediction of peptide retentio ...... sis of amino acid composition.
@en
P2860
P356
P1476
Prediction of peptide retentio ...... sis of amino acid composition.
@en
P2093
P2860
P304
P356
10.1073/PNAS.77.3.1632
P407
P577
1980-03-01T00:00:00Z