14281-57-3Relevant academic research and scientific papers
Postsynthetic Modification of Phenylalanine Containing Peptides by C-H Functionalization
Terrey, Myles J.,Perry, Carole C.,Cross, Warren B.
, p. 104 - 108 (2019/01/11)
New methods for peptide modification are in high demand in drug discovery, chemical biology, and materials chemistry; methods that modify natural peptides are particularly attractive. A Pd-catalyzed, C-H functionalization protocol for the olefination of phenylalanine residues in peptides is reported, which is compatible with common amino acid protecting groups, and the scope of the styrene reaction partner is broad. Bidentate coordination of the peptide to the catalyst appears crucial for the success of the reaction.
Pd-catalyzed intramolecular C(sp2)-H amination of phenylalanine moieties in dipeptides: Synthesis of indoline-2-carboxylate-containing dipeptides
Zheng, Yong,Song, Weibin,Zhu, Yefu,Wei, Bole,Xuan, Lijiang
supporting information, p. 2402 - 2405 (2018/04/12)
A palladium-catalyzed intramolecular C(sp2)-H amination of phenylalanine moieties in dipeptides is described. By this protocol, a series of indoline-2-carboxylate-containing dipeptides were synthesized from dipeptides. The N-protected amino aci
Fragmentation-Rearrangement of Peptide Backbones Mediated by the Air Pollutant NO2.
Gamon, Luke F.,Nathanael, Joses G.,Taggert, Bethany I.,Henry, Fraser A.,Bogena, Jana,Wille, Uta
, p. 14924 - 14930 (2015/10/20)
The fragmentation-rearrangement of peptide backbones mediated by nitrogen dioxide, NO2., was explored using di-, tri-, and tetrapeptides 8-18 as model systems. The reaction, which is initiated through nonradical N-nitrosation of the peptide bond, shortens the peptide chain by the expulsion of one amino acid moiety with simultaneous fusion of the remaining molecular termini through formation of a new peptide bond. The relative rate of the fragmentation-rearrangement depends on the nature of the amino acids and decreases with increasing steric bulk at the α carbon in the order Gly>Ala>Val. Peptides that possessed consecutive aromatic side chains only gave products that resulted from nitrosation of the sterically less congested N-terminal amide. Such backbone fragmentation-rearrangement occurs under physiologically relevant conditions and could be an important reaction pathway for peptides, in which sections without readily oxidizable side chains are exposed to the air pollutant NO2.. In addition to NO2.-induced radical oxidation processes, this outcome shows that ionic reaction pathways, in particular nitrosation, should be factored in when assessing NO2. reactivity in biological systems.
