Predicting Mutation-Induced Stark Shifts in the Active
Site of a Protein with a Polarized Force Field
- Publication date
- Publisher
Abstract
The
electric field inside a protein has a significant effect on
the protein structure, function, and dynamics. Recent experimental
developments have offered a direct approach to measure the electric
field by utilizing a nitrile-containing inhibitor as a probe that
can deliver a unique vibration to the specific site of interest in
the protein. The observed frequency shift of the nitrile stretching
vibration exhibits a linear dependence on the electric field at the
nitrile site, thus providing a direct measurement of the relative
electric field. In the present work, molecular dynamics simulations
were carried out to compute the electric field shift in human aldose
reductase (hALR2) using a polarized protein-specific charge (PPC)
model derived from fragment-based quantum-chemistry calculations in
implicit solvent. Calculated changes of electric field in the active
site of hALR2 between the wild type and mutants were directly compared
with measured vibrational frequency shifts (Stark shifts). Our study
demonstrates that the Stark shifts calculated using the PPC model
are in much better agreement with the experimental data than widely
used nonpolarizable force fields, indicating that the electronic polarization
effect is important for the accurate prediction of changes in the
electric field inside proteins