posted on 2018-04-20, 00:00authored byJon Uranga, Jon I. Mujika, Rafael Grande-Aztatzi, Jon M. Matxain
Hydroxyl radical (•OH) is known to
be highly reactive. Herein, we analyze the oxidation of acid (Asp
and Glu), base (Arg and Lys), and amide (Asn and Gln) containing amino
acid derivatives by the consecutive attack of two •OH. In this work, we study the reaction pathway by means of density
functional theory. The oxidation mechanism is divided into two steps:
(1) the first •OH can abstract a H atom or an electron,
leading to a radical amino acid derivative, which is the intermediate
of the reaction and (2) the second •OH can abstract
another H atom or add itself to the formed radical, rendering the
final oxidized products. The studied second attack of •OH is applicable to situations where high concentration of •OH is found, e.g., in vitro. Carbonyls are the best known oxidation
products for these reactions. This work includes solvent dielectric
and confirmation’s effects of the reaction, showing that both
are negligible. Overall, the most favored intermediates of the oxidation
process at the side chain correspond to the secondary radicals stabilized
by hyperconjugation. Intermediates show to be more stable in those
cases where the spin density of the unpaired electron is lowered.
Alcohols formed at the side chains are the most favored products,
followed by the double-bond-containing ones. Interestingly, Arg and
Lys side-chain scission leads to the most favored carbonyl-containing
oxidation products, in line with experimental results.