Advanced Potential Energy Surfaces for Molecular Simulation

Albaugh, Alex; Boateng, Henry A.; Bradshaw, Richard T.; Demerdash, Omar; Dziedzic, Jacek; Mao, Yuezhi; Margul, Daniel T.; Swails, Jason M.; Qiao, Zhongliang; Case, David A.; Eastman, Peter; Wang, Lee‐Ping; Essex, Jonathan W.; Head‐Gordon, Martin; Pande, Vijay S.; Ponder, Jay W.; Shao, Yihan; Skylaris, Chris Kriton; Todorov, Ilian T.; Tuckerman, Mark E.; Head‐Gordon, Teresa

doi:10.1021/acs.jpcb.6b06414

Cited by 86 publications

(80 citation statements)

References 172 publications

(362 reference statements)

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“…Figure S5 in the Supplementary Material and Figure 2 in Ref. 155 for preliminary results), it might exacerbate the so-called "electron-spill" effect, 156 i.e., the QM region is enormously over-polarized so that the electrons are pulled out of the QM region, and energetically it results in vastly overestimated polarization energies (see Figure S6 and the right panel of Figure S5 in the Supplementary Material). This is related to the aforementioned splitting of multipole moments which effectively places point charges of large magnitude (nuclei of MM atoms) near the QM/MM boundary, while the essential deficiency, nonetheless, is the purely empirical treatment of the repulsive vdW interaction (also termed exchange/Pauli/non-electrostatic repulsion), which fails to preclude the over-polarization of QM density by the electrostatic potential of MM.…”

Section: Discussion and Outlookmentioning

confidence: 99%

Performance of the AMOEBA Water Model in the Vicinity of QM Solutes: A Diagnosis Using Energy Decomposition Analysis

Mao¹,

Shao

Dziedzic

et al. 2017

J. Chem. Theory Comput.

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The importance of incorporating solvent polarization effects into the modeling of solvation processes has been well-recognized, and therefore a new generation of hybrid quantum mechanics/molecular mechanics (QM/MM) approaches that accounts for this effect is desirable. We present a fully self-consistent, mutually polarizable QM/MM scheme using the AMOEBA force field, in which the total energy of the system is variationally minimized with respect to both the QM electronic density and the MM induced dipoles. This QM/AMOEBA model is implemented through the Q-Chem/LibEFP code interface and then applied to the evaluation of solute-solvent interaction energies for various systems ranging from the water dimer to neutral and ionic solutes (NH 3 , NH

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Section: Discussion and Outlookmentioning

confidence: 99%

Performance of the AMOEBA Water Model in the Vicinity of QM Solutes: A Diagnosis Using Energy Decomposition Analysis

Mao¹,

Shao

Dziedzic

et al. 2017

J. Chem. Theory Comput.

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“…Using Gromacs 47 , the 25 lowest energy structures were explicitly solvated using a pre-equilibrated water box. We then performed 50 ps equilibration and then 50 ps production runs in the NPT ensemble using the Tinker software package [49][50][51] and the AMOEBA polarizable force field 45,49 to provide a high quality description of electrostatics in the active site and overall scaffold and solvent. The substrate geometry for the transition state The electric field is projected onto each bond and the value reported is given by the mean of the electric field at the two atoms involved 34 .…”

Section: Methodsmentioning

confidence: 99%

Computational Optimization of Electric Fields for Improving Catalysis of a Designed Kemp Eliminase

Vaissier

Sharma²,

Schaettle³

et al. 2017

ACS Catal.

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145

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Here we report a computational method to improve efficiency of a de novo designed Kemp Eliminase enzyme KE15, by identifying mutations that enhance electric fields and chemical positioning of the substrate that contribute to free energy stabilization of the transition state.Starting from the design that has a kcat/KM of 27 M -1 s -1 , the most improved variant introduced 4 computationally targeted mutations to yield a kcat/KM of 403 M -1 s -1 , with almost all of the enzyme improvement realized through a 43-fold improvement in kcat, indicative of a direct impact on the chemical step. This work raises the prospect of computationally designing enzymes that achieve better efficiency with more minimal experimental intervention using electric field optimization as guidance. † authors contributed equally

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“…However, polarizable models come with an increase in computational expense that in turn limits needed sampling. Nonetheless, recent efforts to reduce the computational expense of polarizable models are starting to take hold 141 , and thus will be an important future direction in the simulation of robust IDP structural ensembles.…”

Section: Computational Methods and Future Innovationsmentioning

confidence: 99%

Finding Our Way in the Dark Proteome

Bhowmick¹,

Brookes²,

Yost³

et al. 2016

J. Am. Chem. Soc.

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113

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The traditional structure-function paradigm has provided significant insights for well-folded proteins in which structures can be easily and rapidly revealed by X-ray crystallography beamlines. However approximately one third of the human proteome are comprised of intrinsically disordered proteins and regions (IDPs/IDRs) that do not adopt a dominant well-folded structure, and therefore remain “unseen” by traditional structural biology methods. This Perspective article considers the challenges raised by the “Dark Proteome”, in which determining the diverse conformational substates of IDPs in their free states, in encounter complexes of bound states, and in complexes retaining significant disorder, requires an unprecedented level of integration of multiple and complementary solution-based experiments that are analyzed with state-of-the art molecular simulation, Bayesian probabilistic models, and high throughput computation. We envision how these diverse experimental and computational tools can work together through formation of a “computational beamline” that will allow key functional features to be identified in IDP structural ensembles.

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Advanced Potential Energy Surfaces for Molecular Simulation

Cited by 86 publications

References 172 publications

Performance of the AMOEBA Water Model in the Vicinity of QM Solutes: A Diagnosis Using Energy Decomposition Analysis

Performance of the AMOEBA Water Model in the Vicinity of QM Solutes: A Diagnosis Using Energy Decomposition Analysis

Computational Optimization of Electric Fields for Improving Catalysis of a Designed Kemp Eliminase

Finding Our Way in the Dark Proteome

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