Direct Look at the Electric Field in Ketosteroid Isomerase and Its Variants

Hennefarth, Matthew R.; Alexandrova, Anastassia N.

doi:10.1021/acscatal.0c02795

Cited by 37 publications

(80 citation statements)

References 65 publications

(194 reference statements)

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“…In particular optimal alignment of electric elds with large eld strengths can directly affect the energy pro le of chemical reactions through the chemical bonds of the transition states that are well aligned, and thus can signi cantly change the reaction product selectivity and catalysis. 23,26,30,31,32,33,34 When we project the electric elds onto the water molecule chemical bonds as a proxy reaction, we nd that the electric eld alignment with the free O-H bonds of surface molecules increases by ~ 30 MV/cm over that of hydrogen-bonded waters in the inner droplet, with eld strengths which can certainly activate strong bonds or break weak chemical bonds altogether. Our works shows that the nature of chemical reactivity at the air-water interface is not just about structural organization, but about electronic organization at the interface, and supports recent work that has suggested an alternative explanation for surface pH involving charge transfer 35 .…”

Section: Introductionmentioning

confidence: 99%

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Hao

Leven

Head‐Gordon

2021

Preprint

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Reaction rates of common organic reactions have been reported to increase by one to six orders of magnitude in aqueous microdroplets compared to bulk solution, but the reasons for the rate acceleration are poorly understood. We investigate the role of electric fields at water droplet surfaces that might explain the promotion of unusual reactive chemistry, along with changes in electric field profiles as a function of excess charge to model the electrospray fragmentation process. We find that electric field alignments along free O-H bonds at the surface yield field strength distributions that are ~30 MV/cm larger on average than that found for O-H bonds in the interior of the water droplet, consistent with greater surface reactivity. We emphasize the importance of both nuclear and electronic effects at the surface, and the non-linear coupling of intramolecular solute polarization with intermolecular solvent modes, as a necessary feature for predicting the higher field strengths at water droplet surfaces.

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Section: Introductionmentioning

confidence: 99%

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Hao

Leven

Head‐Gordon

2021

Preprint

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“…In both the KSI and Diels-Alder reactions, we have shown that topologically similar electric fields correspond to similar barriers of the corresponding reaction [19,47]. Furthermore, we showed how fields only at discrete points (which is what is often computed/measured) do not fully capture a relationship to the reaction barrier [47]. Instead, a more global, 3-D geometry of the electric field around relevant bonds are predictive of the reactivity.…”

Section: Understanding the Optimal Electric Fieldmentioning

confidence: 82%

Advances in optimizing enzyme electrostatic preorganization

Hennefarth

Alexandrova

2022

Current Opinion in Structural Biology

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Utilizing electric fields to catalyze chemical reactions is not a new idea, but in enzymology it undergoes a renaissance, inspired by Warhsel's concept of electrostatic preorganization. According to this concept, the source of the immense catalytic efficiency of enzymes is the intramolecular electric field that permanently favors the reaction transition state over the reactants. Within enzyme design, computational efforts have fallen short in designing enzymes with natural-like efficacy. The outcome could improve if long-range electrostatics (often omitted in current protocols) would be optimized. Here, we highlight the major developments in methods for analyzing and designing electric fields generated by the protein scaffolds, in order to both better understand how natural enzymes function, and aid artificial enzyme design.

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“…Indeed, both contributions are by definition intimately coupled for determining the reaction rates, as better chemical positioning should correlate with better electric field alignment. 43 , 44 In fact we found that the chemical positioning (i.e., the optimization of the active site base that interacts directly with the substrate) overwhelmingly improved the electric field alignments relative to the original design after 7 rounds of LDE of the catalytic base in KE07-R7. 27 …”

Section: Designed Enzymesmentioning

confidence: 87%

Catalytic Principles from Natural Enzymes and Translational Design Strategies for Synthetic Catalysts

Head‐Gordon

2020

ACS Cent. Sci.

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As biocatalysts, enzymes are characterized by their high catalytic efficiency and strong specificity but are relatively fragile by requiring narrow and specific reactive conditions for activity. Synthetic catalysts offer an opportunity for more chemical versatility operating over a wider range of conditions but currently do not reach the remarkable performance of natural enzymes. Here we consider some new design strategies based on the contributions of nonlocal electric fields and thermodynamic fluctuations to both improve the catalytic step and turnover for rate acceleration in arbitrary synthetic catalysts through bioinspired studies of natural enzymes. With a focus on the enzyme as a whole catalytic construct, we illustrate the translational impact of natural enzyme principles to synthetic enzymes, supramolecular capsules, and electrocatalytic surfaces.

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Direct Look at the Electric Field in Ketosteroid Isomerase and Its Variants

Cited by 37 publications

References 65 publications

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Advances in optimizing enzyme electrostatic preorganization

Catalytic Principles from Natural Enzymes and Translational Design Strategies for Synthetic Catalysts

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