Abstract
The elementary mechanism of radical-mediated peptide tyrosine nitration, which is a hallmark of post-translational modification of proteins under nitrative stress in vivo, has been elucidated in detail by using an integrated approach that combines the gas-phase synthesis of prototypical molecular tyrosine-containing peptide radical cations, ion–molecule reactions, and isotopic labeling experiments with DFT calculations. This reaction first involves the radical recombination of .NO2 towards the prerequisite phenoxyl radical tautomer of a tyrosine residue, followed by proton rearrangements, finally yielding the stable and regioselective 3-nitrotyrosyl residue product. In contrast, nitration with the π-phenolic radical cation tautomer is inefficient. This first direct experimental evidence for the elementary steps of the radical-mediated tyrosine nitration mechanism in the gas phase provides a fundamental insight into the regioselectivity of biological tyrosine ortho-nitration.
| Original language | English |
|---|---|
| Pages (from-to) | 331-335 |
| Journal | Chemistry - A European Journal |
| Volume | 26 |
| Issue number | 1 |
| Online published | 28 Oct 2019 |
| DOIs | |
| Publication status | Published - 2 Jan 2020 |
Research Keywords
- isomerization
- nitration
- radical reactions
- reaction mechanisms
- regioselectivity