Predicting Activity Cliffs with Free-Energy Perturbation

Pérez‐Benito, Laura; Casajuana-Martín, Nil; Jiménez‐Rosés, Mireia; Vlijmen, Herman van; Tresadern, Gary

doi:10.1021/acs.jctc.8b01290

Cited by 48 publications

(85 citation statements)

References 68 publications

(91 reference statements)

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“…This may or may not be valid, depending on each and every case under study; when invalid, however, its predictions will fail badly. Thus, for example, when the free energy changes more or less discontinuously with molecular structure, as it does for the case of free energy cliffs [94], there is no way such an ML algorithm will in general be able to spot such phenomena. It could only do so if the coverage of the state space were exceptionally dense, implying that the data upon which it has been trained would need to be enormous.…”

Section: Methods For Free Energy Calculationmentioning

confidence: 99%

Rapid, accurate, precise and reproducible ligand–protein binding free energy prediction

et al. 2020

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A central quantity of interest in molecular biology and medicine is the free energy of binding of a molecule to a target biomacromolecule. Until recently, the accurate prediction of binding affinity had been widely regarded as out of reach of theoretical methods owing to the lack of reproducibility of the available methods, not to mention their complexity, computational cost and time-consuming procedures. The lack of reproducibility stems primarily from the chaotic nature of classical molecular dynamics (MD) and the associated extreme sensitivity of trajectories to their initial conditions. Here, we review computational approaches for both relative and absolute binding free energy calculations, and illustrate their application to a diverse set of ligands bound to a range of proteins with immediate relevance in a number of medical domains. We focus on ensemble-based methods which are essential in order to compute statistically robust results, including two we have recently developed, namely thermodynamic integration with enhanced sampling and enhanced sampling of MD with an approximation of continuum solvent. Together, these form a set of rapid, accurate, precise and reproducible free energy methods. They can be used in real-world problems such as hit-to-lead and lead optimization stages in drug discovery, and in personalized medicine. These applications show that individual binding affinities equipped with uncertainty quantification may be computed in a few hours on a massive scale given access to suitable high-end computing resources and workflow automation. A high level of accuracy can be achieved using these approaches.

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Section: Methods For Free Energy Calculationmentioning

confidence: 99%

Rapid, accurate, precise and reproducible ligand–protein binding free energy prediction

et al. 2020

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“…In turn, application of FEP to a vast range of protein-ligand systems revealed that the method can indeed deliver accurate relative binding affinity predictions with an error of <1 kcal mol À1 with respect to experiment. [23][24][25][26][27][28][29][30][31][32][33][34][35][36] However, the application of FEP using most MD soware remains challenging, preventing its widescale uptake.…”

Section: Introductionmentioning

confidence: 99%

Large scale relative protein ligand binding affinities using non-equilibrium alchemy

et al. 2020

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“…For comparison, it has been reported that FEP+ takes 86 minutes to sample a 1ns perturbation for 12 windows on 4 NVIDIA Tesla K80 for BACE1 69 complexes (containing 401 amino acids) and 34 minutes for the corresponding simulations of the solvated ligands. 70 This corresponds to ~29 min/ns for the complex and ~11 min/ns for the ligand-only simulations, respectively. The Gromacs-FEP implementation was reported to be 3 to 6 times slower than FEP+.…”

Section: Computational Costmentioning

confidence: 98%

“…However, there is evidence that shorter calculations times (usually 1 ns) may be sufficient to obtain a reasonable free energy estimate for certain classes of perturbations. 23,70 Thus, there may be scope to further…”

Section: Computational Costmentioning

confidence: 99%

Automated Assessment of Binding Affinity via Alchemical Free Energy Calculations

Kühn¹,

Firth-Clark²,

Tosco³

et al. 2020

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Free energy calculations have seen increased usage in structure-based drug design. Despite the rising interest, automation of the complex calculations and subsequent analysis of their results are still hampered by the restricted choice of available tools. In this work, an application for automated setup and processing of free energy calculations is presented. Several sanity checks for assessing the reliability of the calculations were implemented, constituting a distinct advantage over existing open-source tools. The underlying workflow is built on top of the software Sire, SOMD, BioSimSpace and OpenMM and uses the AMBER14SB and GAFF2.1 force fields. It was validated on two datasets originally composed by Schrödinger, consisting of 14 protein structures and 220 ligands. Predicted binding affinities were in good agreement with experimental values. For the larger dataset the average correlation coefficient Rp was 0.70 ± 0.05 and average Kendall’s τ was 0.53 ± 0.05 which is broadly comparable to or better than previously reported results using other methods. <br>

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Predicting Activity Cliffs with Free-Energy Perturbation

Cited by 48 publications

References 68 publications

Rapid, accurate, precise and reproducible ligand–protein binding free energy prediction

Rapid, accurate, precise and reproducible ligand–protein binding free energy prediction

Large scale relative protein ligand binding affinities using non-equilibrium alchemy

Automated Assessment of Binding Affinity via Alchemical Free Energy Calculations

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