BIOMAT Database Logo BIOMAT Database Logo

Analysis of Arginylated Peptides by Subtractive Edman Degradation. 2023

Anna S Kashina, and John R Yates Iii
Department of Animal Biology, School of Veterinary Medicine, University of Pennsylvania, Philadelphia, PA, USA. akashina@upenn.edu.

During the early studies of N-terminal arginylation, Edman degradation was widely used to identify N-terminally added Arg on protein substrates. This old method is reliable, but highly depends on the purity and abundance of samples and can become misleading unless a highly purified highly arginylated protein can be obtained. Here, we report a mass spectrometry-based method that utilizes Edman degradation chemistry to identify arginylation in more complex and less abundant protein samples. This method can also apply to the analysis of other posttranslational modifications.

UI MeSH Term Description Entries
D010455 Peptides Members of the class of compounds composed of AMINO ACIDS joined together by peptide bonds between adjacent amino acids into linear, branched or cyclical structures. OLIGOPEPTIDES are composed of approximately 2-12 amino acids. Polypeptides are composed of approximately 13 or more amino acids. PROTEINS are considered to be larger versions of peptides that can form into complex structures such as ENZYMES and RECEPTORS. Peptide,Polypeptide,Polypeptides
D011499 Protein Processing, Post-Translational Any of various enzymatically catalyzed post-translational modifications of PEPTIDES or PROTEINS in the cell of origin. These modifications include carboxylation; HYDROXYLATION; ACETYLATION; PHOSPHORYLATION; METHYLATION; GLYCOSYLATION; ubiquitination; oxidation; proteolysis; and crosslinking and result in changes in molecular weight and electrophoretic motility. Amino Acid Modification, Post-Translational,Post-Translational Modification,Post-Translational Protein Modification,Posttranslational Modification,Protein Modification, Post-Translational,Amino Acid Modification, Posttranslational,Post-Translational Amino Acid Modification,Post-Translational Modifications,Post-Translational Protein Processing,Posttranslational Amino Acid Modification,Posttranslational Modifications,Posttranslational Protein Processing,Protein Processing, Post Translational,Protein Processing, Posttranslational,Amino Acid Modification, Post Translational,Modification, Post-Translational,Modification, Post-Translational Protein,Modification, Posttranslational,Modifications, Post-Translational,Modifications, Post-Translational Protein,Modifications, Posttranslational,Post Translational Amino Acid Modification,Post Translational Modification,Post Translational Modifications,Post Translational Protein Modification,Post Translational Protein Processing,Post-Translational Protein Modifications,Processing, Post-Translational Protein,Processing, Posttranslational Protein,Protein Modification, Post Translational,Protein Modifications, Post-Translational
D011506 Proteins Linear POLYPEPTIDES that are synthesized on RIBOSOMES and may be further modified, crosslinked, cleaved, or assembled into complex proteins with several subunits. The specific sequence of AMINO ACIDS determines the shape the polypeptide will take, during PROTEIN FOLDING, and the function of the protein. Gene Products, Protein,Gene Proteins,Protein,Protein Gene Products,Proteins, Gene
D001120 Arginine An essential amino acid that is physiologically active in the L-form. Arginine Hydrochloride,Arginine, L-Isomer,DL-Arginine Acetate, Monohydrate,L-Arginine,Arginine, L Isomer,DL Arginine Acetate, Monohydrate,Hydrochloride, Arginine,L Arginine,L-Isomer Arginine,Monohydrate DL-Arginine Acetate
D013058 Mass Spectrometry An analytical method used in determining the identity of a chemical based on its mass using mass analyzers/mass spectrometers. Mass Spectroscopy,Spectrometry, Mass,Spectroscopy, Mass,Spectrum Analysis, Mass,Analysis, Mass Spectrum,Mass Spectrum Analysis,Analyses, Mass Spectrum,Mass Spectrum Analyses,Spectrum Analyses, Mass

Related Publications

Anna S Kashina, and John R Yates Iii
[26] Subtractive Edman degradation.
January 1972, Methods in enzymology,
Anna S Kashina, and John R Yates Iii
[28] Subtractive Edman degradation with an insoluble reagent.
January 1972, Methods in enzymology,
Anna S Kashina, and John R Yates Iii
Determination of the chirality of amino acid residues in the course of subtractive Edman degradation of peptides.
September 1991, Analytical biochemistry,
Anna S Kashina, and John R Yates Iii
Edman degradation sequence analysis of resin-bound peptides synthesized by 9-fluorenylmethoxycarbonyl chemistry.
January 1993, Peptide research,
Anna S Kashina, and John R Yates Iii
Manual edman degradation of proteins and peptides.
January 1984, Methods in molecular biology (Clifton, N.J.),
Anna S Kashina, and John R Yates Iii
Identification of glycosylation sites in mucin peptides by edman degradation.
January 2000, Methods in molecular biology (Clifton, N.J.),
Anna S Kashina, and John R Yates Iii
Additive Edman degradation to sequence small peptides.
January 1971, Nature,
Anna S Kashina, and John R Yates Iii
Sequencing hydroxyethylamine-containing peptides via Edman degradation.
October 2002, Organic letters,
Anna S Kashina, and John R Yates Iii
[Protein sequencing analysis by manual Edman degradation].
August 1986, Tanpakushitsu kakusan koso. Protein, nucleic acid, enzyme,
Anna S Kashina, and John R Yates Iii
[Edman degradation of peptides ionically fixed on alumina].
January 1970, Justus Liebigs Annalen der Chemie,
Copied contents to your clipboard!