Computer simulations using molecular dynamics (MD) and the combined quantum mechanical/molecular mechanical (QM/MM) approach are capable of describing structures and dynamics of proteins and chemical reactions catalyzed by enzymes. An accurate and computationally efficient energy function is necessary. However, challenges remain: the accuracy of QM method, the compatibility between the electron density of the QM subsystem and classical force fields for the MM subsystem, and the cost of ab initio QM/MM methods capitalizing on the accuracy and reliability of the associated QM approaches. To address these challenges, we have developed a series of ab initio QM/MM approaches on reaction path optimizations and free energy calculations, the QM/MM minimum free-energy path (QM/MM-MFEP) and the QM/MM neural network (QM/MM-NN) methods. This proposal aims to develop further the ab initio QM/MM methodology and its applications to the studies of redox processes in important enzymes, and the construction of ab initio force fields combined with neural network representations. Our long-term goals are to develop and establish accurate first-principles based and density functional theory (DFT) based MD and QM/MM simulation as an equal partner with experiments for the study of enzymes and proteins and to provide insight into chemical and redox processes in biological systems.
Our aims are as follows: (1) We aim to make ab initio QM/MM models for much more accurate QM/MM energies, for the QM description and for the electrostatic and vdW interactions between the QM and MM subsystems. (2) We aim to develop a combined computational model to explore the key molecular determinants of the reduction potential variability in metalloproteins. We will provide detailed insight into chemical and redox reaction mechanisms in biological systems, in particular laccases. (3) We aim at the development of accurate force fields of water, and proteins for simulations in biological applications, going beyond the traditional force field forms and limitation in accuracy. The proposed developments will capitalize on the theoretical developments in quantum electronic theory, such as the linear response theory and accurate many-electron approach for non-covalent interactions, and leverage machine-learning methods in data science for biological system simulations. The proposed work will lead to the major advancement of the ab initio QM/MM method and force fields, and insights into the structure-function paradigm for proteins and important redox process and reaction mechanisms in enzymes. In addition, it will also lead to methodology development for design of new drugs and enzyme inhibitors.

Public Health Relevance

Understanding chemical reactions and redox processes in solution and in enzymes is of critical importance, because the structure-function relationship and the catalytic role of enzymes are fundamental insights in biochemical research, and they are essential for the development of new or better inhibitors and enzymes. Quantitative tools such as simulations make key contributions to the investigation of the structure-function relationship, complementing experimental studies. This proposal aims at developing methods for simulating structures and dynamics in proteins, and chemical and redox processes catalyzed by enzymes, and investigating the mechanisms of important enzymes-copper protein laccases, leading to significant advances in research tools for studying enzymes and contributing to the understanding of life processes, as well as aiding in the design of inhibitors and drugs.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM061870-18
Application #
10001530
Study Section
Macromolecular Structure and Function D Study Section (MSFD)
Program Officer
Lyster, Peter
Project Start
2000-07-01
Project End
2023-08-31
Budget Start
2020-09-01
Budget End
2021-08-31
Support Year
18
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Duke University
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
044387793
City
Durham
State
NC
Country
United States
Zip Code
27705
Su, Neil Qiang; Li, Chen; Yang, Weitao (2018) Describing strong correlation with fractional-spin correction in density functional theory. Proc Natl Acad Sci U S A 115:9678-9683
Shen, Lin; Zeng, Xiancheng; Hu, Hao et al. (2018) Accurate Quantum Mechanical/Molecular Mechanical Calculations of Reduction Potentials in Azurin Variants. J Chem Theory Comput 14:4948-4957
Shen, Lin; Yang, Weitao (2018) Molecular Dynamics Simulations with Quantum Mechanics/Molecular Mechanics and Adaptive Neural Networks. J Chem Theory Comput 14:1442-1455
Al-Saadon, Rachael; Sutton, Christopher; Yang, Weitao (2018) Accurate Treatment of Charge-Transfer Excitations and Thermally Activated Delayed Fluorescence Using the Particle-Particle Random Phase Approximation. J Chem Theory Comput 14:3196-3204
Wang, Hao; Yang, Weitao (2018) Force Field for Water Based on Neural Network. J Phys Chem Lett 9:3232-3240
Sutton, Christopher; Yang, Yang; Zhang, Du et al. (2018) Single, Double Electronic Excitations and Exciton Effective Conjugation Lengths in ?-Conjugated Systems. J Phys Chem Lett 9:4029-4036
Chen, Zehua; Zhang, Du; Jin, Ye et al. (2017) Multireference Density Functional Theory with Generalized Auxiliary Systems for Ground and Excited States. J Phys Chem Lett 8:4479-4485
Jin, Ye; Zhang, Du; Chen, Zehua et al. (2017) Generalized Optimized Effective Potential for Orbital Functionals and Self-Consistent Calculation of Random Phase Approximations. J Phys Chem Lett 8:4746-4751
Lewis Jr, Charles A; Shen, Lin; Yang, Weitao et al. (2017) Three Pyrimidine Decarboxylations in the Absence of a Catalyst. Biochemistry 56:1498-1503
Wu, Jingheng; Shen, Lin; Yang, Weitao (2017) Internal force corrections with machine learning for quantum mechanics/molecular mechanics simulations. J Chem Phys 147:161732

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