posted on 2023-02-09, 15:35authored byJeisson
D. Corredor, Camilo Febres-Molina, Gonzalo A. Jaña, Verónica A. Jiménez
Vildagliptin
(VIL) is an antidiabetic drug that inhibits dipeptidyl
peptidase-4 (DPP4) through a covalent mechanism. The molecular bases
for this inhibitory process have been addressed experimentally and
computationally. Nevertheless, relevant issues remain unknown such
as the roles of active site protonation states and conserved water
molecules nearby the catalytic center. In this work, molecular dynamics
simulations were applied to examine the structures of 12 noncovalent
VIL-DPP4 complexes encompassing all possible protonation states of
three noncatalytic residues (His126, Asp663, Asp709) that were inconclusively
predicted by different computational tools. A catalytically competent
complex structure was only achieved in the system with His126 in its
ε-form and nonconventional neutral states for Asp663/Asp709.
This complex suggested the involvement of one water molecule in the
catalytic process of His740/Ser630 activation, which was confirmed
by QM/MM simulations. Our findings support the suitability of a novel
water-mediated mechanism in which His740/Ser630 activation occurs
concertedly with the nucleophilic attack on VIL and the imidate protonation
by Tyr547. Then, the restoration of His740/ Tyr547 protonation states
occurs via a two-water hydrogen bonding network in a low-barrier process,
thus describing the final step of the catalytic cycle for the first
time. Additionally, two hydrolytic mechanisms were proposed based
on the hydrogen bonding networks formed by water molecules and the
catalytic residues along the inhibitory mechanism. These findings
are valuable to unveil the molecular features of the covalent inhibition
of DPP4 by VIL and support the future development of novel derivatives
with improved structural or mechanistic profiles.