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The oxidation of L-proline (Pro) by HO● radical in water and the influence
of transition metal ions on this process has been revisited by using the
density functional theory (DFT) method at the
M05-2X/6-311++G(3df,3pd)//M05-2X/6-311++G(d,p) level of theory at the
temperature of 298.15 K. HO●-initiated oxidation of Pro via hydrogen atom
transfer (HAT) reactions is more favourable at the b- and g-carbon than at
the a- and d-carbon. The total branching ratios are 44.6% and 39.5% for
the β- and γ-carbon and 11.5% and 4.2% for the a- and d-carbon,
respectively. The overall rate constant at 298.15 K is 6.04 × 108 M-1 s-1.
In addition, Pro tends to form the stable mono- and bi-dentate complexes
with both Fe and Cu ions via the –COO functional group of dipole-salt
form. The most stable Cu(II)-Pro complexes have high potential oxidant
risks by enhancing the HO● radical formation in the presence of reducing
agents such as superoxide anion or ascorbate anion. Besides, the complexes
of the metal at a high oxidation state, i.e., Fe(III)-Pro and Cu(II)-Pro,
show their ability to be oxidized by HO● radical via HAT reactions but
with a lower rate constant than that of free Pro. Unsurprisingly, the
oxidation enhancement is insignificant for SET reactions with almost
negligible rate constants. In contrast, the rate constants of SET
reactions of low oxidation state complexes (i.e., Fe(II)-Pro and
Cu(I)-Pro) are faster than the oxidation rate of free ligands, and thus,
these complexes promote the oxidation of Pro.
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