2 research outputs found
Effects of Protonation and C5 Methylation on the Electrophilic Addition Reaction of Cytosine: A Computational Study
The mechanism for the effects of protonation and C5 methylation
on the electrophilic addition reaction of Cyt has been explored by
means of CBS-QB3 and CBS-QB3/PCM methods. In the gas phase, three
paths, two protonated paths (N3 and O2 protonated paths B and C) as
well as one neutral path (path A), were mainly discussed, and the
calculated results indicate that the reaction of the HSO<sub>3</sub><sup>–</sup> group with neutral Cyt is unlikely because of
its high activation free energy, whereas O2-protonated path (path
C) is the most likely to occur. In the aqueous phase, path B is the
most feasible mechanism to account for the fact that the activation
free energy of path B decreases compared with the corresponding path
in the gas phase, whereas those of paths A and C increase. The main
striking results are that the HSO<sub>3</sub><sup>–</sup> group
directly interacts with the C5î—»C6 bond rather than the N3î—»C4
bond and that the C5 methylation, compared with Cyt, by decreasing
values of global electrophilicity index manifests that C5 methylation
forms are less electrophilic power as well as by decreasing values
of NPA charges on C5 site of the intermediates make the trend of addition
reaction weaken, which is in agreement with the experimental observation
that the rate of 5-MeCyt reaction is approximately 2 orders of magnitude
slower than that of Cyt in the presence of bisulfite. Apart from cis
and trans isomers, the rare third isomer where both the CH<sub>3</sub> and SO<sub>3</sub> occupy axial positions has been first found in
the reactions of neutral and protonated 5-MeCyt with the HSO<sub>3</sub><sup>–</sup> group. Furthermore, the transformation of the
third isomer from the cis isomer can occur easily
Reactivity of 5-carboxycytosine toward addition and hydrogen abstraction by ·OH in acetonitrile: a computational study
<p>Two distinct mechanisms of -mediated 5-carboxylcytosine (5-caCyt) at the CBS-QB3 approach with polarizable continuum model in acetonitrile have firstly been explored, the addition reaction (paths R1 and R2), the H-atom abstraction reaction (paths R3-R6), respectively. It indicates that the addition of to the C5 = C6 double bond of 5-caCyt remains more favourable than the H-atom abstraction, whether in the gas or aqueous phase. Meanwhile, there is a little difference in the free energy barrier between acetonitrile and water, showing that the solvent has small impact on the reactivity of -mediated 5-caCyt.</p