posted on 2016-02-19, 20:59authored byJing Wang, Jiande Gu, Minh Tho Nguyen, Greg Springsteen, Jerzy Leszczynski
A step-by-step mechanistic pathway following the transformation
of formamide to purine through a five-membered ring intermediate has
been explored by density functional theory computations. The highlight
of the mechanistic route detailed here is that the proposed pathway
represents the simplest reaction pathway. All necessary reactants
are generated from a single starting compound, formamide, through
energetically viable reactions. Several important reaction steps are
involved in this mechanistic route: formylation-dehydration, Leuckart
reduction, five- and six-membered ring-closure, and deamination. On
the basis of the study of noncatalytic pathways, catalytic water has
been found to provide energetically viable step-by-step mechanistic
pathways. Among these reaction steps, five-member ring-closure is
the rate-determining step. The energy barrier (ca. 42 kcal/mol) of
this rate-control step is somewhat lower than the rate-determining
step (ca. 44 kcal/mol) for a pyrimidine-based pathway reported previously.
The mechanistic pathway reported herein is less energetically demanding
than for previously proposed routes to adenine.