posted on 2015-04-14, 00:00authored byIgnacio Viciano, Patricio González-Navarrete, Juan Andrés, Sergio Martí
Bonding evolution theory (BET), as
a combination of the electron
localization function (ELF) and Thom’s catastrophe theory (CT),
has been coupled with quantum mechanics/molecular mechanics (QM/MM)
method in order to study biochemical reaction paths. The evolution
of the bond breaking/forming processes and electron pair rearrangements
in an inhomogeneous dynamic environment provided by the enzyme has
been elucidated. The proposed methodology is applied in an enzymatic
system in order to clarify the reaction mechanism for the hydrogen
abstraction of the androstenedione (ASD) substrate catalyzed by the
cytochrome P450 aromatase enzyme. The use of a QM/MM Hamiltonian allows
inclusion of the polarization of the charges derived from the amino
acid residues in the wave function, providing a more accurate and
realistic description of the chemical process. The hydrogen abstraction
step is found to have five different ELF structural stability domains,
whereas the C–H breaking and O–H forming bond process
rearrangements are taking place in an asynchronous way.