Kemp elimination catalysts by computational enzyme design

Röthlisberger, Daniela; Khersonsky, Olga; Wollacott, Andrew M.; Jiang, Lin; DeChancie, Jason; Betker, Jamie L.; Gallaher, Jasmine L.; Althoff, Eric A.; Zanghellini, Alexandre; Dym, Orly; Albeck, Shira; Houk, K. N.; Tawfik, Dan S.; Baker, David

doi:10.1038/nature06879

Cited by 1,183 publications

(1,297 citation statements)

References 32 publications

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“…To our knowledge, in silico studies of enzymes with non-natural substrates are scarce, and we therefore seek to find a theoretical framework for prediction of reactivity, catalytic power, and productive combinations of enzyme species and substrates. Unlike most other computational design studies which focus on optimum transition state stabilization, including the groundbreaking de novo designed enzymes by Baker and collegues, [31,32] we attempt to monitor the full reaction pathway, including substrate binding and substrate-substrate interactions. This approach is supported by a very recent study by Simón and Goodman, [33] who show that oxyanion holes are not optimized for maximum TS stabilization, but rather for minimizing the reaction barrier.…”

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confidence: 99%

Computational design of a lipase for catalysis of the Diels-Alder reaction

et al. 2010

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Combined molecular docking, molecular dynamics (MD) and density functional theory (DFT) studies have been employed to study catalysis of the Diels-Alder reaction by a modified lipase. Six variants of the versatile enzyme {\em Candida Antarctica} lipase B (CALB) have been rationally engineered {\em in silico} based on the specific characteristics of the pericyclic addition. A kinetic analysis reveals that hydrogen bond stabilization of the transition state and substrate binding are key components of the catalytic process. In the case of substrate binding, which has the greater potential for optimization, both binding strength and positioning of the substrates are important for catalytic efficiency. The binding strength is determined by hydrophobic interactions and can be tuned by careful selection of solvent and substrates. The MD simulations show that substrate positioning is sensitive to cavity shape and size, and can be controlled by a few rational mutations. The well-documented S105A mutation is essential to enable sufficient space in the vicinity of the oxyanion hole. Moreover, bulky residues on the edge of the active site hinders the formation of a sandwich-like near-attack conformer (NAC), and the I189A mutation is needed to obtain enough space above the face of the $\alpha$,$\beta$-double bond on the dienophile. The double mutant S105A/I189A performs quite well for two of three dienophiles. Based on binding constants and NAC energies obtained from MD simulations combined with activation energies from DFT computations, relative catalytic rates ($v_{cat}/v_{uncat}$) of up to $10^3$ are predicted.Response to Reviewers: We are happy with the favorable comments by the reviewers. We have have corrected the manuscript as suggested by reviewer 1 1. A sentence explaining catalytic promiscuity has been added. 2. A paragraph discussing the relationship between the NAC concept and the Reaction Force has been added.We have shortened the manuscript as suggested by reviewer 2. In particular, we have moved information regarding the structural relaxation of protein structure in MD simulations to the supplementary material. Abstract Combined molecular docking, molecular dynamics (MD) and density functional theory (DFT) studies have been employed to study catalysis of the DielsAlder reaction by a modified lipase. Six variants of the versatile enzyme Candida Antarctica lipase B (CALB) have been rationally engineered in silico based on the specific characteristics of the pericyclic addition. A kinetic analysis reveals that hydrogen bond stabilization of the transition state and substrate binding are key components of the catalytic process. In the case of substrate binding, which has the greater potential for optimization, both binding strength and positioning of the substrates are important for catalytic efficiency. The binding strength is determined by hydrophobic interactions and can be tuned by careful selection of solvent and substrates. The MD simulations show that substrate positioning is sensitive to cavity s...

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Section: Fig 1: (A)mentioning

confidence: 99%

Computational design of a lipase for catalysis of the Diels-Alder reaction

et al. 2010

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“…[10][11][12][13] The development of new specific functions in an enzyme is something that Nature has already made during done through evolution, although the specific paths evolutionary routes followed to reach this goal remain, in general, raveled to be revealed. While closely related proteins can have different functions, some distantly related enzymes can have the same or similar function.…”

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confidence: 99%

Enzyme Promiscuity in Enolase Superfamily. Theoretical Study of o-Succinylbenzoate Synthase Using QM/MM Methods

et al. 2015

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The promiscuous activity of the enzyme o-Succinylbenzoate Synthase (OSBS) from the actinobacteria Amycolatopsis is investigated by means of QM/MM methods, using both Density Functional Theory and Semiempirical Hamiltonians. This enzyme catalyzes not only the dehydration of 2-succinyl-6R-hydroxy-2,4-cyclohexadiene-1R-carboxylate but also catalyzes racemization of different acylaminoacids, being N-succinyl-Rphenylglycine the best substrate. We investigated the molecular mechanisms for both reactions exploring the Potential Energy Surface. Then, Molecular Dynamics simulations were performed to obtain the free energy profiles and the averaged interaction energies of enzymatic residues with the reacting system. Our results confirm the plausibility of the reaction mechanisms proposed in the literature, with a good agreement between theoretical and experimentally-derived activation free energies. Our simulations unravel the role played by the different residues in each of the two possible reactions. The presence of flexible loops in the active site and the selection of structural modifications in the substrate seem to be key elements to promote the promiscuity of this enzyme.

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“…7,8 Iterative rounds of computational design, both in the active site and surrounding residues, place mutations to stabilize the transition state with the aim of accelerating the target reaction. Successes of this approach include redesigned proteins with activities for the Kemp elimination, 9 and the retroaldol 10 and Diels-Alder 11 reactions. Often only moderate efficiencies are achieved, although these can be further improved by directed evolution.…”

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confidence: 99%

Installing hydrolytic activity into a completely de novo protein framework

et al. 2016

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Designing enzyme-like catalysts tests our understanding of sequence-tostructure/function relationships in proteins. Here, we install hydrolytic activity predictably into a completely de novo and thermo-stable -helical barrel, which comprises 7 helices arranged around an accessible channel. We show that the lumen of the barrel accepts 21 mutations to functional polar residues. The resulting variant, which has cysteine-histidine-glutamic acid triads on each helix, hydrolyses pnitrophenyl acetate with catalytic efficiencies matching the most-efficient redesigned hydrolases based on natural protein scaffolds. This is the first report of a functional catalytic triad engineered into a de novo protein framework. The flexibility of our system also allows the facile incorporation of unnatural side chains to improve activity and probe the catalytic mechanism. Such predictable and robust construction of truly de novo biocatalysts holds promise for applications in chemical and biochemical synthesis.(134 words)

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Kemp elimination catalysts by computational enzyme design

Cited by 1,183 publications

References 32 publications

Computational design of a lipase for catalysis of the Diels-Alder reaction

Computational design of a lipase for catalysis of the Diels-Alder reaction

Enzyme Promiscuity in Enolase Superfamily. Theoretical Study of o-Succinylbenzoate Synthase Using QM/MM Methods

Installing hydrolytic activity into a completely de novo protein framework

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