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

Vaissier, Valérie; Sharma, Sudhir C.; Schaettle, K. B.; Zhang, Taoran; Head‐Gordon, Teresa

doi:10.1021/acscatal.7b03151

Cited by 84 publications

(155 citation statements)

References 53 publications

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“…8 Markland and co-workers confirmed that the scaffold exerts an overall stabilizing electric field from ab initio molecular dynamics (AIMD) simulations that include Nuclear Quantum Effects (NQE) 16 13,16 ; this is because the electric field calculated in the reactant and transition states are different and cannot be factorized in front of the reaction dipole difference. 8,22 Starting from the original design with a kcat/KM of 27 M -1 s -1 , we created a computationally improved variant through introduction of 4 targeted mutations to yield a kcat/KM of 403 M -1 s -1 .…”

Section: Natural and Synthetic Biocatalysismentioning

confidence: 99%

“…Shown is the location of the 4 mutations of KE15 best variant (left) and the total electric field contributions to the transition state relative to the original design (right). 22 The positive direction for the bond dipole is the same as for the electric field (from C to H, from N to C and from O to N for the CH, CN and ON bond respectively with magnitude +1 , +0.4 and +2.3 Debye). The efficiency of these computationally designed variants was measured and confirmed experimentally.…”

Section: Natural and Synthetic Biocatalysismentioning

confidence: 99%

“…The most desirable solution is a full ab initio molecular dynamics (AIMD) treatment of large catalytic environments for thousands of atoms and hundreds of nanoseconds (or longer), but this is well beyond current capabilities of AIMD. Bridging this length and time scale gap will be realized through algorithmic developments that would decrease the number of cycles in the self-consistent cycle of AIMD 74 , substantially increase the time step in a stable manner 75 , achieving linear scaling in an accurate and reliable way 76 , as well as coupling AIMD to the Grand Canonical ensemble 77 , and use of advanced sampling methods 78 such as the low energy alternative side chain arrangements of an enzyme using Monte Carlo (MC) to create QM/MC approaches to determine fluctuating electric fields 22,79 . The emergence of more detailed molecular in situ and operando catalytic experiments 80…”

Section: Summary and Future Directionsmentioning

confidence: 99%

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Computational optimization of electric fields for better catalysis design

2018

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Although the ubiquitous role that long-ranged electric fields play in catalysis has been recognized, it is seldom used as a primary design parameter in the discovery of new catalytic materials. Here we illustrate how electric fields have been used to computationally optimize biocatalytic performance of a synthetic enzyme, and how they could be used as a unifying descriptor for catalytic design across a range of homogeneous and heterogeneous catalysts. While focusing on electrostatic environmental effects may open new routes toward the rational optimization of efficient catalysts, much more predictive capacity is required of theoretical methods to have a transformative impact in their computational design-and thus experimental relevance-when using electric field alignments in the reactive centres of complex catalytic systems.

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Section: Natural and Synthetic Biocatalysismentioning

confidence: 99%

Section: Natural and Synthetic Biocatalysismentioning

confidence: 99%

Section: Summary and Future Directionsmentioning

confidence: 99%

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Computational optimization of electric fields for better catalysis design

2018

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“…The results summarized here may also potentially be relevant to the in silico design [156] of zeolite adsorbents and catalysts, where different zeolite frameworks, could be compared based whether they provide the ideal long-range electrostatic and dispersion interactions, which lead to the most effective stabilization of adsorbed substrates and TSs. In a similar vein, recent studies on electric field optimization in enzymes have emphasized on the importance of electrostatics [157] in the protein scaffolding surrounding the active site, and have even reported computational strategies to improve the efficiency of electric field catalysis in de novo designed Kemp eliminases [158]. Lastly, we note from a theoretical perspective, that Energy Decomposition Analysis (EDA) and Principal Component Analysis (PCA) [118] are promising tools with regards to deconvoluting the contributions of longrange electrostatics and dispersion in selective TS stabilization.…”

Section: Model Detailsmentioning

confidence: 99%

Impact of long-range electrostatic and dispersive interactions on theoretical predictions of adsorption and catalysis in zeolites

et al. 2018

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In this paper, we review the importance of long-range zeolite framework interactions in theoretical predictions for a variety of zeolite-catalyzed processes, and we show why such interactions must be determined accurately in order to reproduce experimentally measured adsorption and activation energies. We begin with an overview of the different strategies that have been used to account for long-range coulombic and dispersive interactions of zeolite framework atoms with species adsorbed at an active site. These methods include full periodic-DFT calculations and multi-layer hybrid techniques. Electrostatic interactions are observed to have a more significant impact than dispersive interactions on the geometries of ion-pair transition states and adsorbed species. Stabilization of the TS relative to reactant complexes is also dictated by electrostatic interactions. Dispersion effects are found to significantly stabilize both transition and reactant states for adsorbed species, especially those which have dimensions that provide good fits within the zeolite pore or cavity. We also show that the relevance of particular active site configurations can be missed, if the effects of long-range interactions are neglected. As a case in point, we demonstrate that a site previously considered inactive for ethane dehydrogenation, [GaH 2 ] + may in fact be more active than previously thought, when the impact of long-range interactions on the predicted activation energy is taken into account. Finally, the use of hybrid quantum mechanics/molecular mechanics approaches on extended, finite zeolite clusters has emerged as an accurate, highly cost-effective, and versatile alternative towards overcoming some of the present-day limitations of periodic calculations.

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“…[4] The systematic absence of experimentally determinedv alues of Z has likely impeded ar igorous understanding of most chemicalp rocesses in which proteinsa re involved including aggregation and self-assembly, [20][21][22][23][24][25][26] ligand binding, [27][28][29][30][31][32][33][34] catalysis, [35][36][37][38][39] electron transfer, [3,6,[40][41][42][43][44][45][46][47] protein crystallization, [14,48] analytical separation, [49,50] and protein engineering. [51][52][53][54][55][56] It is tempting to assume that the formal net chargeo faprotein predicted from generalized residue pK a values (Z seq )issosimilar to the actual net charge that any difference is irrelevant, and the isoelectric point tells us all we need to know about ap rotein's net charge. Thep K a of individual amino acid residues in folded proteins can vary by severalu nits (possibly as many as 10 units) from textbook values because of solventb urial, dipole-dipole interactions, or metal coordination.…”

Section: Introductionmentioning

confidence: 99%

What Are We Missing by Not Measuring the Net Charge of Proteins?

Zahler

Shaw

2019

Chemistry A European J

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The net electrostatic charge (Z) of a folded protein in solution represents a bird's eye view of its surface potentials—including contributions from tightly bound metal, solvent, buffer, and cosolvent ions—and remains one of its most enigmatic properties. Few tools are available to the average biochemist to rapidly and accurately measure Z at pH≠pI. Tools that have been developed more recently seem to go unnoticed. Most scientists are content with this void and estimate the net charge of a protein from its amino acid sequence, using textbook values of pKa. Thus, Z remains unmeasured for nearly all folded proteins at pH≠pI. When marveling at all that has been learned from accurately measuring the other fundamental property of a protein—its mass—one wonders: what are we missing by not measuring the net charge of folded, solvated proteins? A few big questions immediately emerge in bioinorganic chemistry. When a single electron is transferred to a metalloprotein, does the net charge of the protein change by approximately one elementary unit of charge or does charge regulation dominate, that is, do the pKa values of most ionizable residues (or just a few residues) adjust in response to (or in concert with) electron transfer? Would the free energy of charge regulation (ΔΔGz) account for most of the outer sphere reorganization energy associated with electron transfer? Or would ΔΔGz contribute more to the redox potential? And what about metal binding itself? When an apo‐metalloprotein, bearing minimal net negative charge (e.g., Z=−2.0) binds one or more metal cations, is the net charge abolished or inverted to positive? Or do metalloproteins regulate net charge when coordinating metal ions? The author's group has recently dusted off a relatively obscure tool—the “protein charge ladder”—and used it to begin to answer these basic questions.

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

Cited by 84 publications

References 53 publications

Computational optimization of electric fields for better catalysis design

Computational optimization of electric fields for better catalysis design

Impact of long-range electrostatic and dispersive interactions on theoretical predictions of adsorption and catalysis in zeolites

What Are We Missing by Not Measuring the Net Charge of Proteins?

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