Gaussian Accelerated Molecular Dynamics in OpenMM

Copeland, Matthew M.; Hung, N.; Votapka, Lane; Joshi, Keya; Wang, Jinan; Amaro, Rommie E.; Miao, Yinglong

doi:10.1021/acs.jpcb.2c03765

Cited by 9 publications

(24 citation statements)

References 78 publications

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“…In implicit solvent, AIBMD also identified five low-energy conformational states of alanine dipeptide, including β-sheet centered around (-160°, 150°), PII around (-62°, 140°) and (-90°, 61°), α L around (56°, 34°), and α R around (-70°, -27°) ( Figure 2e ). The 1D and 2D free energy profiles of (Φ, Ψ) calculated from AIBMD simulations were in excellent agreements with previous GaMD simulations performed by AMBER 27 , NAMD 29 , and OpenMM 30 . Therefore, simulations of alanine dipeptide have demonstrated the enhanced sampling capability as well as accuracy of AIBMD for both explicit and implicit solvent systems.…”

Section: Resultssupporting

confidence: 86%

“…The 1D and 2D free energy profiles of (Φ, Ψ) calculated from AIBMD simulations were in excellent agreements with previous GaMD simulations performed by AMBER 27 , NAMD 29 , and OpenMM 30 . Therefore, simulations of alanine dipeptide have demonstrated the enhanced sampling capability as well as accuracy of AIBMD for both explicit and implicit solvent systems.…”

Section: Aibmd Simulations Of Alanine Dipeptidesupporting

confidence: 86%

“…GaMD has been successfully demonstrated on enhanced sampling of ligand binding, protein folding, protein conformational change, as well as protein-membrane, protein-protein, and protein-nucleic acid interactions 3 . GaMD has been implemented in widely used simulation packages including AMBER 27 , NAMD 29 , OpenMM 30 , GENESIS 31 , and TINKER-HP 32 .…”

Section: Introductionmentioning

confidence: 99%

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Deep Boosted Molecular Dynamics (DBMD): Accelerating molecular simulations with Gaussian boost potentials generated using probabilistic Bayesian deep neural network

Hung

Miao

2023

Preprint

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We have developed a new Artificial Intelligence Boosted Molecular Dynamics (AIBMD) method. Probabilistic Bayesian neural network models were implemented to construct boost potentials that exhibit Gaussian distribution with minimized anharmonicity, thereby allowing for accurate energetic reweighting and enhanced sampling of molecular simulations. AIBMD was demonstrated on model systems of alanine dipeptide and the fast-folding protein and RNA structures. For alanine dipeptide, 30ns AIMBD simulations captured up to 83-125 times more backbone dihedral transitions than 1μs conventional molecular dynamics (cMD) simulations and were able to accurately reproduce the original free energy profiles. Moreover, AIBMD sampled multiple folding and unfolding events within 300ns simulations of the chignolin model protein and identified low-energy conformational states comparable to previous simulation findings. Finally, AIBMD captured a general folding pathway of three hairpin RNAs with the GCAA, GAAA, and UUCG tetraloops. Based on Deep Learning neural network, AIBMD provides a powerful and generally applicable approach to boosting biomolecular simulations. AIBMD is available with open source in OpenMM at https://github.com/MiaoLab20/AIBMD/.

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Section: Resultssupporting

confidence: 86%

Section: Aibmd Simulations Of Alanine Dipeptidesupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

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Deep Boosted Molecular Dynamics (DBMD): Accelerating molecular simulations with Gaussian boost potentials generated using probabilistic Bayesian deep neural network

Hung

Miao

2023

Preprint

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“…GaMD , is developed to apply a harmonic boost potential to enhance sampling with reduced energetic noise. The boost potential normally exhibits a near Gaussian distribution, which enables proper reweighting of the free energy profiles through cumulant expansion to the second order. , GaMD has been successfully applied to simulate important biomolecular processes, including protein/RNA folding, ,, ligand/protein/RNA binding, ,− and protein conformational changes. ,, However, it remained challenging to accurately predict ligand binding kinetic rates through normal GaMD. , Recently, a “selective GaMD” algorithm, called Ligand GaMD (LiGaMD), , has been developed to allow for more efficient sampling of ligand binding and dissociation processes, which thus allows to accurately predict the ligand binding kinetic rates. For the protein ligand binding system, the system contains ligand L , protein P , and the biological environment E. The system potential energy could be decomposed into the following terms V ( r ) = V P , b ( r P ) + V L , b ( r L ) + V E , b ( r E ) + V P P , n b ( r P ) + V L L , n b …”

Section: Molecular Dynamics and Enhanced Sampling Methods For Predict...mentioning

confidence: 99%

“…The boost potential normally exhibits a near Gaussian distribution, which enables proper reweighting of the free energy profiles through cumulant expansion to the second order. 28,29 GaMD has been successfully applied to simulate important biomolecular processes, including protein/RNA folding, 29,108,109 ligand/ protein/RNA binding, 108,110−116 and protein conformational changes. 115,117,118 However, it remained challenging to accurately predict ligand binding kinetic rates through normal GaMD.…”

Section: Molecular Dynamics and Enhanced Sampling Methods For Predict...mentioning

confidence: 99%

Predicting Biomolecular Binding Kinetics: A Review

Wang

Hung

Koirala

et al. 2023

J. Chem. Theory Comput.

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Biomolecular binding kinetics including the association (k on ) and dissociation (k of f ) rates are critical parameters for therapeutic design of smallmolecule drugs, peptides, and antibodies. Notably, the drug molecule residence time or dissociation rate has been shown to correlate with their efficacies better than binding affinities. A wide range of modeling approaches including quantitative structure-kinetic relationship models, Molecular Dynamics simulations, enhanced sampling, and Machine Learning has been developed to explore biomolecular binding and dissociation mechanisms and predict binding kinetic rates. Here, we review recent advances in computational modeling of biomolecular binding kinetics, with an outlook for future improvements.

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Flexible Gaussian Accelerated Molecular Dynamics to Enhance Biological Sampling

Gracia Carmona,

Oostenbrink

2023

J. Chem. Theory Comput.

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Molecular dynamics simulations often struggle to obtain sufficient sampling to study complex molecular events due to high energy barriers separating the minima of interest. Multiple enhanced sampling techniques have been developed and improved over the years to tackle this issue. Gaussian accelerated molecular dynamics (GaMD) is a recently developed enhanced sampling technique that works by adding a biasing potential, lifting the energy landscape up, and decreasing the height of its barriers. GaMD allows one to increase the sampling of events of interest without the need of a priori knowledge of the system or the relevant coordinates. All required acceleration parameters can be obtained from a previous search run. Upon its development, several improvements for the methodology have been proposed, among them selective GaMD in which the boosting potential is selectively applied to the region of interest. There are currently four selective GaMD methods that have shown promising results. However, all of these methods are constrained on the number, location, and scenarios in which this selective boosting potential can be applied to ligands, peptides, or protein−protein interactions. In this work, we showcase a GROMOS implementation of the GaMD methodology with a fully flexible selective GaMD approach that allows the user to define, in a straightforward way, multiple boosting potentials for as many regions as desired. We show and analyze the advantages of this flexible selective approach on two previously used test systems, the alanine dipeptide and the chignolin peptide, and extend these examples to study its applicability and potential to study conformational changes of glycans and glycosylated proteins.

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Gaussian Accelerated Molecular Dynamics in OpenMM

Cited by 9 publications

References 78 publications

Deep Boosted Molecular Dynamics (DBMD): Accelerating molecular simulations with Gaussian boost potentials generated using probabilistic Bayesian deep neural network

Deep Boosted Molecular Dynamics (DBMD): Accelerating molecular simulations with Gaussian boost potentials generated using probabilistic Bayesian deep neural network

Predicting Biomolecular Binding Kinetics: A Review

Flexible Gaussian Accelerated Molecular Dynamics to Enhance Biological Sampling

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