Mass spectrometry allows direct identification of proteins in large genomes
about
sameAs
Human neuroglobin protein in cerebrospinal fluidWhole proteome analysis of post-translational modifications: applications of mass-spectrometry for proteogenomic annotationIntegration with the human genome of peptide sequences obtained by high-throughput mass spectrometryGenome annotation of Anopheles gambiae using mass spectrometry-derived data.HybGFS: a hybrid method for genome-fingerprint scanningWhole human genome proteogenomic mapping for ENCODE cell line data: identifying protein-coding regionsProteomic profiling of the planarian Schmidtea mediterranea and its mucous reveals similarities with human secretions and those predicted for parasitic flatwormsIntroduction to computational proteomicsProteogenomics: concepts, applications and computational strategiesNovel gene and gene model detection using a whole genome open reading frame analysis in proteomics.Accelerating string set matching in FPGA hardware for bioinformatics researchExploiting proteomic data for genome annotation and gene model validation in Aspergillus niger.An integrated mass-spectrometry pipeline identifies novel protein coding-regions in the human genomeBrain proteomics of Anopheles gambiae.Proteogenomics to discover the full coding content of genomes: a computational perspective.Shotgun proteomics aids discovery of novel protein-coding genes, alternative splicing, and "resurrected" pseudogenes in the mouse genomeGenome-based peptide fingerprint scanning.Gapped spectral dictionaries and their applications for database searches of tandem mass spectra.A proteogenomic analysis of Anopheles gambiae using high-resolution Fourier transform mass spectrometry.Improving gene annotation using peptide mass spectrometryInference and validation of protein identifications.Application of LC-MS/MS MRM to Determine Staphylococcal Enterotoxins (SEB and SEA) in Milk.Proteogenomics: Integrating Next-Generation Sequencing and Mass Spectrometry to Characterize Human Proteomic VariationIdentification and characterization of a novel ubiquitous nucleolar protein 'NARR' encoded by a gene overlapping the rab34 oncogene.Incorporating sequence information into the scoring function: a hidden Markov model for improved peptide identification.The bacterial proteogenomic pipelineIdentification of protein phosphorylation sites by a combination of mass spectrometry and solid phase Edman sequencing.Protein cleavage strategies for an improved analysis of the membrane proteome.Deep coverage of the Escherichia coli proteome enables the assessment of false discovery rates in simple proteogenomic experiments.Ortho-proteogenomics: multiple proteomes investigation through orthology and a new MS-based protocol.
P2860
Q24555825-2C73209A-1494-4F14-843E-A2525C26F3D4Q24676843-5776CAB3-3F62-419C-8212-3A10C504B661Q24805791-79D3C9E3-6AB3-4876-ACC6-2A56F76B9856Q24816748-76B3144A-D807-43AB-9733-8F877099C157Q27496508-949C9814-CEBC-4494-A9B8-171540DB7294Q27496606-499DCDAC-09C2-4AF6-8639-DEA0AA566857Q28267815-0DE4EFB4-0B24-431F-AE45-1E3298E6440FQ28469269-7F5343F4-B62C-4D94-87E1-C97AF457B5EEQ28649850-D753BF91-2054-471E-B184-24D596F63263Q30477869-23545B39-E85C-4A51-9C20-44DFA651172BQ33328320-B07A042E-99D5-4059-9D26-0DDE3993CEEBQ33405632-8D2503D8-860C-4FF8-871C-68FC11B13C0CQ33529076-812C9081-0770-41AB-A05A-11E2ED63274DQ33860220-320406A5-41A4-4C7B-9139-1298BF43FA8DQ34172476-AEC01A3E-5115-4046-8F14-E3C85FDC8E75Q34175322-49813A04-1F2D-4227-AF65-0667C4D70C37Q34466229-35E3CC13-26EF-49E1-BB0D-C9B7C764674FQ35026856-539ACCF8-450B-4FC8-80B9-D220F4BB1970Q35493861-6903E178-BA11-46A0-8434-8B2CBB655818Q35608692-7169A528-6704-4AE1-8312-CC9216D04E9AQ36386951-9BB33030-E361-4A6F-97D4-108D43A04ED6Q36846152-36FEF2C2-CE08-4A44-BC89-97B9B141BB11Q37190570-F82A5A7C-E64B-4A99-A56F-8635FAAFAB8DQ38319665-AFF602F4-2A83-4745-A887-7A35A5736AB1Q41270109-A21FDE09-4B5E-4464-877A-F476A28C46C4Q41673817-A0F17ABF-9462-43F1-B9FD-5879F7691826Q41856458-9909372E-6A9E-4626-A2CB-024895F0F69DQ42638706-898DE1D1-C927-492F-AF2E-6F9F6E412B71Q42917663-A153E88E-64D8-4CCA-83F7-62EE414558D6Q43214369-F6B64416-ED8F-4793-94BE-941D6F1F77E9
P2860
Mass spectrometry allows direct identification of proteins in large genomes
description
2001 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի մայիսին հրատարակված գիտական հոդված
@hy
artículu científicu espublizáu en 2001
@ast
scientific article (publication date: May 2001)
@en
vedecký článok (publikovaný 2001-05)
@sk
vědecký článek publikovaný v roce 2001
@cs
wetenschappelijk artikel (gepubliceerd in 2001-05)
@nl
wissenschaftlicher Artikel
@de
наукова стаття, опублікована в травні 2001
@uk
مقالة علمية (نشرت في مايو 2001)
@ar
name
Mass spectrometry allows direct identification of proteins in large genomes
@ast
Mass spectrometry allows direct identification of proteins in large genomes
@en
Mass spectrometry allows direct identification of proteins in large genomes
@nl
type
label
Mass spectrometry allows direct identification of proteins in large genomes
@ast
Mass spectrometry allows direct identification of proteins in large genomes
@en
Mass spectrometry allows direct identification of proteins in large genomes
@nl
prefLabel
Mass spectrometry allows direct identification of proteins in large genomes
@ast
Mass spectrometry allows direct identification of proteins in large genomes
@en
Mass spectrometry allows direct identification of proteins in large genomes
@nl
P2093
P3181
P1433
P1476
Mass spectrometry allows direct identification of proteins in large genomes
@en
P2093
P304
P3181
P356
10.1002/1615-9861(200104)1:5<641::AID-PROT641>3.3.CO;2-I
P407
P577
2001-05-01T00:00:00Z