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Polarizable AMOEBA Model for Simulating Mg2+·Protein·Nucleotide Complexes.

Julian M Delgado1, Péter R Nagy2,3,4, Sameer Varma1,5

  • 1Department of Molecular Biosciences, University of South Florida, 4202 E. Fowler Avenue, Tampa, Florida 33620, United States.

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|December 5, 2023
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Summary
This summary is machine-generated.

Accurately modeling divalent cations like magnesium (Mg2+) in molecular mechanics (MM) simulations is crucial for understanding enzyme mechanisms. This study refines the AMOEBA model, significantly improving Mg2+ interactions with proteins and ATP for better enzyme simulations.

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Area of Science:

  • Computational chemistry
  • Biophysics
  • Structural biology

Background:

  • Molecular mechanics (MM) simulations offer detailed insights into enzyme mechanisms involving nucleotide cofactors and divalent cations.
  • Modeling divalent cations, particularly Mg2+, in MM simulations remains a significant challenge, with existing polarizable force fields showing large errors in interaction energies and failing to reproduce experimental structures of Mg2+·Protein·ATP complexes.

Purpose of the Study:

  • To systematically assess and critically revise the polarizable AMOEBA model for improved simulation of Mg2+·Protein·ATP complexes.
  • To enhance the predictive performance of MM simulations for enzymes utilizing Mg2+ and nucleotide cofactors.

Main Methods:

  • Revision of the AMOEBA protein model with high field corrections (AMOEBABIO18-HFC) to improve Mg2+-protein interactions.
  • Inclusion of many-body Nonbonded-fix (NB-fix) corrections to further reduce interaction energy errors.
  • Development of a new AMOEBA model for Adenosine Triphosphate (ATP) with revised polarization, van der Waals (vdW), and dihedral parameters.
  • Benchmarking interaction energies against vdW-inclusive density functional theory (DFT) and coupled cluster (CCSD(T)) calculations.
  • Performing molecular dynamics (MD) simulations of Mg2+·Kinase·ATP complexes using the improved models.

Main Results:

  • The revised AMOEBABIO18-HFC model significantly reduced Mg2+-protein interaction energy errors (MAE from 17 to 10 kcal/mol).
  • Incorporating many-body NB-fix corrections further decreased MAE to 6 kcal/mol (<2% error).
  • The new ATP model accurately predicted experimental Mg2+-ATP binding free energy and provided insights into Mg2+ association.
  • MD simulations with the improved models showed better agreement between simulated and experimentally determined structures (X-ray crystallography) of Mg2+·Kinase·ATP complexes.

Conclusions:

  • The refined AMOEBA model, incorporating AMOEBABIO18-HFC and many-body NB-fix corrections, substantially improves the accuracy of simulating Mg2+ interactions in biological systems.
  • The new ATP model enhances the simulation of Mg2+-ATP binding.
  • These advancements enable more reliable MD simulations of Mg2+-dependent enzymes, leading to better structural predictions that align with experimental data.