Protein-peptide association kinetics beyond the seconds timescale from atomistic simulations

Paul, Fabian; Wehmeyer, Christoph; Abualrous, Esam T.; Wu, Hao; Crabtree, Michael D.; Schöneberg, Johannes; Clarke, Jane; Freund, Christian; Weikl, Thomas R.; Noé, Frank

doi:10.1038/s41467-017-01163-6

Cited by 145 publications

(204 citation statements)

References 83 publications

(95 reference statements)

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“…Although molecular dynamics (MD) simulations enable atomic-level observations, they are limited to several microseconds on standard high-performance computers and are thus normally applicable only to relatively fast processes (2). Recently, the kinetics of slower protein interaction processes were explored through long MD simulations spanning timescales of tens of microseconds to milliseconds (3)(4)(5), which were achieved through the development of special-purpose supercomputers for high-speed simulations (e.g., ANTON (6)) and/or algorithms to aggregate many short simulations (e.g., Markov state models (MSMs) (7)). Unfortunately, MD-specific supercomputers such as ANTON are accessible only to a limited number of researchers due to their high costs.…”

Section: Main Textmentioning

confidence: 99%

Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

Araki

Matsumoto

Bekker

et al. 2020

Preprint

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Capturing the dynamic processes of biomolecular systems in atomistic detail remains difficult despite recent experimental advances. Although molecular dynamics (MD) techniques enable atomic-level observations, simulations of "slow" biomolecular processes (with timescales longer than submilliseconds) are challenging, due to current computer speed limitations. Therefore, we developed a new method to accelerate MD simulations by high-frequency ultrasound perturbation. The binding events between the protein CDK2 and its small-molecule inhibitors were nearly undetectable in 100-ns conventional MD, but the new method successfully accelerated their slow binding rates by up to 10-20 times. The accelerated MD simulations revealed a variety of microscopic kinetic features of the inhibitors on the protein surface, such as the existence of different binding pathways to the active site. Moreover, the simulations allowed estimating the corresponding kinetic parameters and exploring other druggable pockets. This method can thus provide deeper insight into the microscopic interactions controlling biomolecular processes. (149 /150 words)

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Section: Main Textmentioning

confidence: 99%

Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

Araki

Matsumoto

Bekker

et al. 2020

Preprint

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“…1 A central challenge in the study of IDPs is the characterization of the mechanisms by which they bind their physiological interaction partners: Mechanistic insight into the folding-upon-binding process of IDPs could ultimately enable a more predictive understanding of how their sequences, conformational propensities, and biophysical properties dictate their interactions and thus their biological activity. An increasing number of experimental, 2-6 theoretical, 7-11 and computational [12][13][14][15][16][17][18][19][20][21] studies have been used to predict or globally characterize molecular recognition in IDPs, but atomic-resolution details have only recently begun to emerge. [3][4][5] Atomistic molecular dynamics (MD) simulations are a promising approach for complementing experimental measurements of IDP folding-upon-binding.…”

Section: Introductionmentioning

confidence: 99%

The mechanism of coupled folding-upon-binding of an intrinsically disordered protein

Robustelli

Piana

Shaw

2020

Preprint

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AbstractIntrinsically disordered proteins (IDPs), which in isolation do not adopt a well-defined tertiary structure but instead populate a structurally heterogeneous ensemble of interconverting states, play important roles in many biological pathways. IDPs often fold into ordered states upon binding to their physiological interaction partners (a so-called “folding-upon-binding” process), but it has proven difficult to obtain an atomic-level description of the structural mechanisms by which they do so. Here, we describe in atomic detail the folding-upon-binding mechanism of an IDP segment to its binding partner, as observed in unbiased molecular dynamics simulations. In our simulations, we observed over 70 binding and unbinding events between the α-helical molecular recognition element (α-MoRE) of the intrinsically disordered C-terminal domain of the measles virus nucleoprotein (NTAIL) and the X domain (XD) of the measles virus phosphoprotein complex. We found that folding-upon-binding primarily occurred through induced-folding pathways (in which intermolecular contacts form before or concurrently with the secondary structure of the disordered protein)—an observation supported by previous experiments—and that the transition state ensemble was characterized by the formation of just a few key intermolecular contacts, and was otherwise highly structurally heterogeneous. We found that when a large amount of helical content was present early in a transition path, NTAIL typically unfolded, then refolded after additional intermolecular contacts formed. We also found that, among conformations with similar numbers of intermolecular contacts, those with less helical content had a higher probability of ultimately forming the native complex than conformations with more helical content, which were more likely to unbind. These observations suggest that even after intermolecular contacts have formed, disordered regions can have a kinetic advantage over folded regions in the folding-upon-binding process.

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“…On the other hand, enhanced sampling MD methods have been developed to improve biomolecular simulations (Christen and van Gunsteren, 2008;Gao et al, 2008;Liwo et al, 2008;Dellago and Bolhuis, 2009;Abrams and Bussi, 2014;Spiwok et al, 2015;Miao and McCammon, 2016). Multi-ensemble Markov models (Paul et al, 2017), which combine cMD with Hamiltonian replica exchange enhanced sampling simulations, have been used to characterize peptide-protein binding and calculate kinetic rates of a nano-molar peptide inhibitor PMI to the MDM2 oncoprotein fragment (Paul et al, 2017). While cMD is able to simulate fast events such as peptide binding, enhanced sampling simulations can capture rare events such as peptide unbinding.…”

Section: Introductionmentioning

confidence: 99%

Improved Modeling of Peptide-Protein Binding through Global Docking and Accelerated Molecular Dynamics Simulations

Wang

Alekseenko

Kozakov

et al. 2019

Preprint

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Peptides mediate up to 40% of known protein-protein interactions in higher eukaryotes and play a key role in cellular signaling, protein trafficking, immunology and oncology. However, it is challenging to predict peptide-protein binding with conventional computational modeling approaches, due to slow dynamics and high peptide flexibility. Here, we present a prototype of the approach which combines global peptide docking using ClusPro PeptiDock and all-atom enhanced simulations using Gaussian accelerated molecular dynamics (GaMD). For three distinct model peptides, the lowest backbone root-mean-square deviations (RMSDs) of their bound conformations relative to X-ray structures obtained from PeptiDock were 3.3 Å -4.8 Å, being medium quality predictions according to the Critical Assessment of PRediction of Interactions (CAPRI) criteria. GaMD simulations refined the peptide-protein complex structures with significantly reduced peptide backbone RMSDs of 0.6 Å -2.7 Å, yielding two high quality (subangstrom) and one medium quality models. Furthermore, the GaMD simulations identified important low-energy conformational states and revealed the mechanism of peptide binding to the target proteins. Therefore, PeptiDock+GaMD is a promising approach for exploring peptideprotein interactions.

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Protein-peptide association kinetics beyond the seconds timescale from atomistic simulations

Cited by 145 publications

References 83 publications

Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

The mechanism of coupled folding-upon-binding of an intrinsically disordered protein

Improved Modeling of Peptide-Protein Binding through Global Docking and Accelerated Molecular Dynamics Simulations

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