posted on 2012-04-10, 00:00authored byKakali Sen, John C. Hackett
Aromatase (CYP19) catalyzes the terminal step in estrogen
biosynthesis,
which requires three separate oxidation reactions, culminating in
an enigmatic aromatization that converts an androgen to an estrogen.
A stable ferric peroxo (Fe3+O22–) intermediate is seen by electron paramagnetic resonance, but its
role in this complex reaction remains controversial. Combining molecular
dynamics simulation and hybrid quantum mechanics/molecular mechanics,
we show that ferric peroxo addition to the 19-aldehyde initiates the
reaction. Stepwise cleavage of the C10–C19 and O–O bonds
of the peroxohemiacetal extrudes formate and yields Compound II, which
in turn desaturates the steroid through successive abstraction of
the 1β-hydrogen atom and deprotonation of the 2β-position.
Throughout the transformation, a proton is cyclically relayed between
D309 and the substrate to stabilize reaction intermediates. This mechanism
invokes novel oxygen intermediates and provides a unifying interpretation
of past experimental mechanistic studies.