about
Identification of direct protein targets of small moleculesProteome-derived peptide libraries to study the substrate specificity profiles of carboxypeptidases.Inferring serum proteolytic activity from LC-MS/MS dataEmerging principles in protease-based drug discovery.Global identification of peptidase specificity by multiplex substrate profiling.Global analysis of cellular proteolysis by selective enzymatic labeling of protein N-termini.In vivo assessment of protease dynamics in cutaneous wound healing by degradomics analysis of porcine wound exudates.Metacaspases.Profiling protease activities by dynamic proteomics workflows.The DegraBase: a database of proteolysis in healthy and apoptotic human cellsCaspase substrates and inhibitorsSystems-level analysis of proteolytic events in increased vascular permeability and complement activation in skin inflammationTime-resolved analysis of the matrix metalloproteinase 10 substrate degradome.Intracellular substrate cleavage: a novel dimension in the biochemistry, biology and pathology of matrix metalloproteinases.Proteomics and the dynamic plasma membrane: Quo Vadis?Bioinformatic approaches for predicting substrates of proteases.What do 'omic technologies have to offer periodontal clinical practice in the future?Natural substrates of plant proteases: how can protease degradomics extend our knowledge?N- and C-terminal degradomics: new approaches to reveal biological roles for plant proteases from substrate identification.Matrix metalloproteinases in cytotoxic lymphocytes impact on tumour infiltration and immunomodulation.Mass spectrometry-based proteomics strategies for protease cleavage site identification.Matrix metalloproteinase processing of signaling molecules to regulate inflammation.Mapping orphan proteases by proteomics: meprin metalloproteases deciphered as potential therapeutic targets.Blessing or curse? Proteomics in granzyme research.C-terminomics: Targeted analysis of natural and posttranslationally modified protein and peptide C-termini.Protease signaling in animal and plant-regulated cell death.Degradomics in Neurotrauma: Profiling Traumatic Brain Injury.Multidimensional Analysis of Protease Substrates and Their Cellular Origins in Mixed Secretomes from Multiple Cell Types.How has urinary proteomics contributed to the discovery of early biomarkers of acute kidney injury?A SILAC-based approach identifies substrates of caspase-dependent cleavage upon TRAIL-induced apoptosis.Monitoring proteolytic processing events by quantitative mass spectrometry.Probing the efficiency of proteolytic events by positional proteomics.An Approach to Incorporate Multi-Enzyme Digestion into C-TAILS for C-Terminomics Studies.Selecting protein N-terminal peptides by combined fractional diagonal chromatography.Protease Substrate Profiling by N-Terminal COFRADIC.Depletion of internal peptides by site-selective blocking, phosphate labeling, and TiO2 adsorption for in-depth analysis of C-terminome.Approaches to identify and characterize microProteins and their potential uses in biotechnology.
P2860
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P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on March 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
MS-driven protease substrate degradomics.
@en
MS-driven protease substrate degradomics.
@nl
type
label
MS-driven protease substrate degradomics.
@en
MS-driven protease substrate degradomics.
@nl
prefLabel
MS-driven protease substrate degradomics.
@en
MS-driven protease substrate degradomics.
@nl
P2093
P356
P1433
P1476
MS-driven protease substrate degradomics.
@en
P2093
Francis Impens
Joël Vandekerckhove
Kim Plasman
Kris Gevaert
Niklaas Colaert
P2860
P304
P356
10.1002/PMIC.200900418
P577
2010-03-01T00:00:00Z