Global absolute quantification of a proteome: Challenges in the deployment of a QconCAT strategy.
about
How drugs get into cells: tested and testable predictions to help discriminate between transporter-mediated uptake and lipoidal bilayer diffusionProteome dynamics: revisiting turnover with a global perspectiveRecent advances in quantitative neuroproteomicsMass spectrometry-based proteomics for pre-eclampsia and preterm birthAsymmetric proteome equalization of the skeletal muscle proteome using a combinatorial hexapeptide libraryLFQuant: a label-free fast quantitative analysis tool for high-resolution LC-MS/MS proteomics data.Quantification of amyloid precursor protein isoforms using quantification concatamer internal standard.The application of selective reaction monitoring confirms dysregulation of glycolysis in a preclinical model of schizophrenia.Protein analysis by shotgun/bottom-up proteomicsBeyond the Western front: targeted proteomics and organelle abundance profilingHigh-throughput production of a stable isotope-labeled peptide library for targeted proteomics using a wheat germ cell-free synthesis system.Direct and Absolute Quantification of over 1800 Yeast Proteins via Selected Reaction Monitoring.Mass spectrometry-based workflow for accurate quantification of Escherichia coli enzymes: how proteomics can play a key role in metabolic engineering.The current status of clinical proteomics and the use of MRM and MRM(3) for biomarker validation.QconCATs: design and expression of concatenated protein standards for multiplexed protein quantification.A critical appraisal of techniques, software packages, and standards for quantitative proteomic analysis.The use of selected reaction monitoring in quantitative proteomics.The complexity of protein semiochemistry in mammals.The selected reaction monitoring/multiple reaction monitoring-based mass spectrometry approach for the accurate quantitation of proteins: clinical applications in the cardiovascular diseases.Translational value of liquid chromatography coupled with tandem mass spectrometry-based quantitative proteomics for in vitro-in vivo extrapolation of drug metabolism and transport and considerations in selecting appropriate techniques.DOSCATs: Double standards for protein quantification.Systematic evaluation of quantotypic peptides for targeted analysis of the human kinome.Harnessing the power of proteomics for identification of oncogenic, druggable signalling pathways in cancer.Quantitation of Vacuolar Sugar Transporter Abundance Changes Using QconCAT Synthtetic Peptides.Protein turnover measurement using selected reaction monitoring-mass spectrometry (SRM-MS).Quantification of extracellular matrix proteins from a rat lung scaffold to provide a molecular readout for tissue engineering.Absolute protein quantification of the yeast chaperome under conditions of heat shock.Absolute quantification of the glycolytic pathway in yeast: deployment of a complete QconCAT approach.An in vivo control map for the eukaryotic mRNA translation machinery.Choice of LC-MS methods for the absolute quantification of drug-metabolizing enzymes and transporters in human tissue: a comparative cost analysis.Absolute quantification of selected proteins in the human osteoarthritic secretome.Prediction of missed proteolytic cleavages for the selection of surrogate peptides for quantitative proteomics.Quantitative analysis of chaperone network throughput in budding yeast.Metal-tag labeling coupled with multiple reaction monitoring-mass spectrometry for absolute quantitation of proteins.Improving the precision of quantitative bottom-up proteomics based on stable isotope-labeled proteins.Targeted Quantification of Isoforms of a Thylakoid-Bound Protein: MRM Method Development.Stoichiometry, Absolute Abundance, and Localization of Proteins in the Bacillus cereus Spore Coat Insoluble Fraction Determined Using a QconCAT Approach.Deciphering multifactorial resistance phenotypes in Acinetobacter baumannii by genomics and targeted label-free proteomics.Highly multiplexed single-cell protein analysis.MEERCAT: Multiplexed Efficient Cell Free Expression of Recombinant QconCATs For Large Scale Absolute Proteome Quantification.
P2860
Q24273350-47230043-B247-4697-B99D-2FB641BA4E0AQ26821916-BBDDC8AC-D07D-49EF-ACE1-698BA61ADDC3Q27000073-4F3C5D8B-4695-4C43-A3CB-F5BD05C74497Q28083761-1078EB6A-D1A2-4E0D-9998-FF4AA059099EQ28741177-8E83A6BE-0951-45BA-8718-5F5B54D1326AQ30574031-22E571B4-23B5-482A-B0C9-0B04749CA5DAQ33564874-DFAE794C-47EF-447C-B0B3-6A9DEA1E7D1FQ34197032-C8F3BF3E-B6E8-4872-A39E-9EA45ADA48A5Q34600986-8FADC224-698B-41A5-89B5-F9A9372F5D6BQ35569275-E3BC925D-64D9-43E1-B463-DA6A29DA1AC8Q36023898-B4F3C0DF-F43E-4C3A-BFA4-837B2D4D74DBQ36778277-CB40D5DA-D380-47BF-BCEC-4A9754BCF3B8Q37687449-4A816E5B-BB21-4397-AA76-F55957EA3737Q38012171-ACCE2DD0-6B0A-45CF-9273-255C3ADC201CQ38024638-C5349523-2865-48B8-9493-D434F80D5333Q38026929-7064F775-CA8B-44B3-A9DF-CF7104325F46Q38033244-3DE292CD-D495-4233-96D1-BAE37586A6F1Q38238617-DAF053CA-EA1E-4BB1-BA15-A48F0707E5D5Q38268586-93469544-6F62-4501-AEC8-A997F81A02F4Q38537236-D54AC6DB-1EB9-4637-ACEC-FB479E2BB2CEQ38861127-80C492C2-860C-491C-BF86-F30DB036AB61Q38963283-CD9D1961-5CBD-4EFD-8A77-F25486C6FF9FQ39175714-22F3630B-5C8B-44A4-A11D-4E710649E45CQ39351032-EE9847B6-B111-43FC-8B49-4ED11470F54FQ39374028-68C29FED-DA46-4A99-8A05-84ECF75B03B0Q39407920-2B593C4B-4FDD-4953-AC78-9ADA825A3D2AQ39716768-530D43B9-43BC-4369-A65C-66AD0C7F6A36Q39766915-99557279-98F1-4172-8777-229993BFACD4Q40087239-EB57F8D5-2F85-406D-A622-C0706490CC86Q41461755-861090C3-24A4-4F1E-BF0B-D0AE5DBF75F0Q42047060-317A02AD-BDAC-45EF-8124-A844CBB26BE1Q42118107-8E8DE953-32B0-4546-8E5E-D4D3086EB383Q42955546-69F78CE6-2875-4CD5-8415-7296818BEADAQ44171931-B8CB6A27-5D7D-4BF5-B7A6-4EB668D20418Q46112925-1D025798-FAE5-4049-A7E6-6647D03A06C4Q46271891-2C708E4D-F922-432E-9EAA-BA4F6C62751CQ47271983-738E32E5-95CD-4849-ADDE-8385D8C83C64Q47273518-46363873-90B9-48F2-BD17-BE6EF2FD7B63Q47342056-E7B84034-EB54-4B48-A358-1EF3F7D6D1FAQ47621471-519F0F58-2DCD-4C72-AFEE-2698D11F515B
P2860
Global absolute quantification of a proteome: Challenges in the deployment of a QconCAT strategy.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 28 June 2011
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Global absolute quantification ...... loyment of a QconCAT strategy.
@en
Global absolute quantification ...... loyment of a QconCAT strategy.
@nl
type
label
Global absolute quantification ...... loyment of a QconCAT strategy.
@en
Global absolute quantification ...... loyment of a QconCAT strategy.
@nl
prefLabel
Global absolute quantification ...... loyment of a QconCAT strategy.
@en
Global absolute quantification ...... loyment of a QconCAT strategy.
@nl
P2093
P2860
P50
P356
P1433
P1476
Global absolute quantification ...... ployment of a QconCAT strategy
@en
P2093
Craig Lawless
Karin Lanthaler
Rachel Watkins
Ronan O'Cualain
Simon J Gaskell
Stephen W Holman
P2860
P304
P356
10.1002/PMIC.201100039
P577
2011-06-28T00:00:00Z