Transient states and barriers from molecular simulations and milestoning theory: kinetics in ligand-protein recognition and compound design

Tang, Zhiye; Chen, Sihan; Chang, Chia‐en A.

doi:10.1101/169607

Cited by 2 publications

(2 citation statements)

References 53 publications

(40 reference statements)

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“…To overcome this limitation, a range of enhanced sampling techniques has been explored recently (Bruce et al, 2018). Some of them are aimed at the reduction of the configurational space to be sampled for the computation of binding kinetic rates, e.g., metadynamics (Tiwary et al, 2015, 2017), weighted ensemble methods (Dickson and Lotz, 2016; Dixon et al, 2018), or milestoning (Tang and Chang, 2017) [a detailed review can be found elsewhere (Mollica et al, 2016; Dickson et al, 2017)]. Although these methods are designed for the prediction of the absolute values of binding and unbinding rates within a reasonable computation time, they are still very computationally demanding and require high user expertise, which impedes the implementation of these methods in drug design pipelines.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Analysis of τRAMD Trajectories to Decipher Molecular Determinants of Drug-Target Residence Times

Kokh

Kaufmann

Kister

et al. 2019

Front. Mol. Biosci.

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Drug-target residence times can impact drug efficacy and safety, and are therefore increasingly being considered during lead optimization. For this purpose, computational methods to predict residence times, τ, for drug-like compounds and to derive structure-kinetic relationships are desirable. A challenge for approaches based on molecular dynamics (MD) simulation is the fact that drug residence times are typically orders of magnitude longer than computationally feasible simulation times. Therefore, enhanced sampling methods are required. We recently reported one such approach: the τRAMD procedure for estimating relative residence times by performing a large number of random acceleration MD (RAMD) simulations in which ligand dissociation occurs in times of about a nanosecond due to the application of an additional randomly oriented force to the ligand. The length of the RAMD simulations is used to deduce τ. The RAMD simulations also provide information on ligand egress pathways and dissociation mechanisms. Here, we describe a machine learning approach to systematically analyze protein-ligand binding contacts in the RAMD trajectories in order to derive regression models for estimating τ and to decipher the molecular features leading to longer τ values. We demonstrate that the regression models built on the protein-ligand interaction fingerprints of the dissociation trajectories result in robust estimates of τ for a set of 94 drug-like inhibitors of heat shock protein 90 (HSP90), even for the compounds for which the length of the RAMD trajectories does not provide a good estimation of τ. Thus, we find that machine learning helps to overcome inaccuracies in the modeling of protein-ligand complexes due to incomplete sampling or force field deficiencies. Moreover, the approach facilitates the identification of features important for residence time. In particular, we observed that interactions of the ligand with the sidechain of F138, which is located on the border between the ATP binding pocket and a hydrophobic transient sub-pocket, play a key role in slowing compound dissociation. We expect that the combination of the τRAMD simulation procedure with machine learning analysis will be generally applicable as an aid to target-based lead optimization.

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Section: Introductionmentioning

confidence: 99%

Machine Learning Analysis of τRAMD Trajectories to Decipher Molecular Determinants of Drug-Target Residence Times

Kokh

Kaufmann

Kister

et al. 2019

Front. Mol. Biosci.

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“…Analyzing the milestone-to-milestone transition statistics via a statis-tical framework, 42 the kinetics and free energy profile are estimated. This method has also been implemented in the software tools miles, 47 ScMile 48 and SEEKR, 49 and has been used to study a variety of complex biological problems including protein allosteric transitions, 50 membrane permeation by small molecules, [51][52][53][54] protein small molecule interaction, 49,[55][56][57] simple ligand-receptor binding, 58 peptide transport through protein channels, 59,60 DNA protein interaction, 61 protein conformational dynamics 62 etc. Apart from the necessity of having a predefined reaction coordinate, the milestones need to be placed far apart to preserve the assumption of Markovianity.…”

Section: Introductionmentioning

confidence: 99%

Markovian Weighted Ensemble Milestoning (M-WEM): Long-time Kinetics from Short Trajectories

Andricioaei

2021

Preprint

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We introduce a rare-event sampling scheme, named Markovian Weighted Ensemble Milestoning (M-WEM), which inlays the weighted ensemble framework within a Markovian milestoning theory to efficiently calculate thermodynamic and kinetic properties of long-timescale biomolecular processes from short atomistic molecular dynamics simulations. We then showcase the application of this method to the Muller Brown potential model, the conformational switching in alanine dipeptide, and the millisecond timescale protein-ligand unbinding in the trypsin-benzamidine complex. Not only can we predict the kinetics of these processes with quantitative accuracy, but we also present a scheme to reconstruct a multidimensional free energy landscape, along additional degrees of freedom which are not part of the milestoning progress coordinate. For the ligand-receptor system, the experimental residence time, association and dissociation kinetics, and binding free energy could be reproduced using M-WEM approach within a few hundreds of nanoseconds simulation time, which is a fraction of the computational cost of other currently available methods, and close to four orders of magnitude less than the experimental residence time. Due to the high accuracy and low computational cost the M-WEM approach can find potential application in kinetics and free energy based computational drug design.

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Transient states and barriers from molecular simulations and milestoning theory: kinetics in ligand-protein recognition and compound design

Cited by 2 publications

References 53 publications

Machine Learning Analysis of τRAMD Trajectories to Decipher Molecular Determinants of Drug-Target Residence Times

Machine Learning Analysis of τRAMD Trajectories to Decipher Molecular Determinants of Drug-Target Residence Times

Markovian Weighted Ensemble Milestoning (M-WEM): Long-time Kinetics from Short Trajectories

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