Issue 8, 2023

Modern non-polarizable force fields diverge in modeling the enzyme–substrate complex of a canonical serine protease

Abstract

Classical molecular dynamics simulation is a powerful and established method of modern computational chemistry. Being able to obtain accurate information on molecular behavior is crucial to get valuable insights into structure–function relationships that translate into fundamental findings and practical applications. Active sites of enzymes are known to be particularly intricate, therefore, simpler non-polarizable force fields may provide an inaccurate description. In this work, we addressed this hypothesis in a case of a canonical serine triad protease trypsin in its complex with a substrate-mimicking inhibitor. We tested six modern and popular force fields to find that significantly diverging results may be obtained. Amber FB-15 and OPLS-AA/M turned out to model the active site incorrectly. Amber ff19sb and ff15ipq demonstrated mixed performance. The best performing force fields were CHARMM36m and Amber ff99sb-ildn, therefore, they are recommended for use with this and related systems. We speculate that a similar lack of cross-force field convergence may be characteristic of other enzymatic systems. Therefore, we advocate for careful consideration of different force fields in any study within the field of computational enzymology.

Graphical abstract: Modern non-polarizable force fields diverge in modeling the enzyme–substrate complex of a canonical serine protease

Supplementary files

Article information

Article type
Paper
Submitted
24 Nov 2022
Accepted
07 Feb 2023
First published
10 Feb 2023

Phys. Chem. Chem. Phys., 2023,25, 6352-6361

Modern non-polarizable force fields diverge in modeling the enzyme–substrate complex of a canonical serine protease

J. Belyaeva, A. Zlobin, V. Maslova and A. Golovin, Phys. Chem. Chem. Phys., 2023, 25, 6352 DOI: 10.1039/D2CP05502C

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