Overcoming an optimization plateau in the directed evolution of highly efficient nerve agent bioscavengers

Goldsmith, Moshe; Aggarwal, Nidhi; Ashani, Yacov; Jubran, Halim; Greisen, Per; Овчинников, С. Г.; Leader, Haim; Baker, David; Sussman, Joel L.; Goldenzweig, Adi; Fleishman, Sarel J.; Tawfik, Dan S.

doi:10.1093/protein/gzx003

Cited by 64 publications

(85 citation statements)

References 61 publications

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“…Probably a major point of interest of this prokaryotic expression system is its possible use as a tool for high-throughput screening of BChE mutants for the development of catalytic bioscavengers, such as what have been done with bacterial phosphotriesterases [ 39 ]. Indeed, BChE variants, such as the Gly117His and Gly117His/Glu197Gln human BChE mutants [ 40 , 41 ] or swine BChE (manuscript in preparation) can catalyze OP hydrolysis.…”

Section: Discussionmentioning

confidence: 99%

Bacterial Expression of Human Butyrylcholinesterase as a Tool for Nerve Agent Bioscavengers Development

Brazzolotto¹,

Igert²,

Guillon³

et al. 2017

Molecules

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Human butyrylcholinesterase is a performant stoichiometric bioscavenger of organophosphorous nerve agents. It is either isolated from outdated plasma or functionally expressed in eukaryotic systems. Here, we report the production of active human butyrylcholinesterase in a prokaryotic system after optimization of the primary sequence through the Protein Repair One Stop Shop process, a structure- and sequence-based algorithm for soluble bacterial expression of difficult eukaryotic proteins. The mutant enzyme was purified to homogeneity. Its kinetic parameters with substrate are similar to the endogenous human butyrylcholinesterase or recombinants produced in eukaryotic systems. The isolated protein was prone to crystallize and its 2.5-Å X-ray structure revealed an active site gorge region identical to that of previously solved structures. The advantages of this alternate expression system, particularly for the generation of butyrylcholinesterase variants with nerve agent hydrolysis activity, are discussed.

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Section: Discussionmentioning

confidence: 99%

Bacterial Expression of Human Butyrylcholinesterase as a Tool for Nerve Agent Bioscavengers Development

Brazzolotto¹,

Igert²,

Guillon³

et al. 2017

Molecules

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“…Next, protein mutants containing combinations of these mutations are then designed using Rosetta combinatorial sequence optimization to identify variants with improved native‐state energy. Such an approach was employed during directed evolution to convert bacterial phosphotriesterases into efficient nerve agent bioscavengers with high activity against both VX and Russian VX . Prior efforts to engineer these phosphotriesterases had reached an optimization plateau short of the catalytic design goals.…”

Section: Design Methods For Improving Directed Evolution Of Protein Amentioning

confidence: 99%

“…Prior efforts to engineer these phosphotriesterases had reached an optimization plateau short of the catalytic design goals. The PROSS design tool was used to guide library design for stabilization of the phosphotriesterases, and this enabled additional productive rounds of directed evolution and incorporation of previously identified beneficial mutations that were not well tolerated when introduced into the less stable phosphotriesterases . PROSS has also been used to stabilize the malaria invasion protein PfRH5, a promising malaria vaccine candidate, without disrupting its immunogenicity or ligand binding .…”

Section: Design Methods For Improving Directed Evolution Of Protein Amentioning

confidence: 99%

Directed evolution methods for overcoming trade‐offs between protein activity and stability

2019

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Engineered proteins are being widely developed and employed in applications ranging from enzyme catalysts to therapeutic antibodies. Directed evolution, an iterative experimental process composed of mutagenesis and library screening, is a powerful technique for enhancing existing protein activities and generating entirely new ones not observed in nature. However, the process of accumulating mutations for enhanced protein activity requires chemical and structural changes that are often destabilizing, and low protein stability is a significant barrier to achieving large enhancements in activity during multiple rounds of directed evolution. Here we highlight advances in understanding the origins of protein activity/stability trade-offs for two important classes of proteins (enzymes and antibodies) as well as innovative experimental and computational methods for overcoming such trade-offs. These advances hold great potential for improving the generation of highly active and stable proteins that are needed to address key challenges related to human health, energy and the environment. K E Y W O R D Saffinity, antibody, catalysis, enzyme, protein design, protein engineering

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“…Other mutants of this enzyme, made by directed evolution and computer design, display a wide spectrum of activity. Not only do they hydrolyze V agents with high efficiency, but also G agents with k cat / K m > 5 × 10 7 M −1 ·min −1 for tabun and sarin (Goldsmith et al, 2017 ). The evolved mutant of PON-1, C23AL, has k cat / K m = 1.2 × 10 7 M −1 ·min −1 for racemic VX (Goldsmith et al, 2016 ).…”

Section: Bioscavenger Conceptmentioning

confidence: 99%

Optimization of Cholinesterase-Based Catalytic Bioscavengers Against Organophosphorus Agents

et al. 2018

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Organophosphorus agents (OPs) are irreversible inhibitors of acetylcholinesterase (AChE). OP poisoning causes major cholinergic syndrome. Current medical counter-measures mitigate the acute effects but have limited action against OP-induced brain damage. Bioscavengers are appealing alternative therapeutic approach because they neutralize OPs in bloodstream before they reach physiological targets. First generation bioscavengers are stoichiometric bioscavengers. However, stoichiometric neutralization requires administration of huge doses of enzyme. Second generation bioscavengers are catalytic bioscavengers capable of detoxifying OPs with a turnover. High bimolecular rate constants (kcat/Km > 106 M−1min−1) are required, so that low enzyme doses can be administered. Cholinesterases (ChE) are attractive candidates because OPs are hemi-substrates. Moderate OP hydrolase (OPase) activity has been observed for certain natural ChEs and for G117H-based human BChE mutants made by site-directed mutagenesis. However, before mutated ChEs can become operational catalytic bioscavengers their dephosphylation rate constant must be increased by several orders of magnitude. New strategies for converting ChEs into fast OPase are based either on combinational approaches or on computer redesign of enzyme. The keystone for rational conversion of ChEs into OPases is to understand the reaction mechanisms with OPs. In the present work we propose that efficient OP hydrolysis can be achieved by re-designing the configuration of enzyme active center residues and by creating specific routes for attack of water molecules and proton transfer. Four directions for nucleophilic attack of water on phosphorus atom were defined. Changes must lead to a novel enzyme, wherein OP hydrolysis wins over competing aging reactions. Kinetic, crystallographic, and computational data have been accumulated that describe mechanisms of reactions involving ChEs. From these studies, it appears that introducing new groups that create a stable H-bonded network susceptible to activate and orient water molecule, stabilize transition states (TS), and intermediates may determine whether dephosphylation is favored over aging. Mutations on key residues (L286, F329, F398) were considered. QM/MM calculations suggest that mutation L286H combined to other mutations favors water attack from apical position. However, the aging reaction is competing. Axial direction of water attack is not favorable to aging. QM/MM calculation shows that F329H+F398H-based multiple mutants display favorable energy barrier for fast reactivation without aging.

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Overcoming an optimization plateau in the directed evolution of highly efficient nerve agent bioscavengers

Cited by 64 publications

References 61 publications

Bacterial Expression of Human Butyrylcholinesterase as a Tool for Nerve Agent Bioscavengers Development

Bacterial Expression of Human Butyrylcholinesterase as a Tool for Nerve Agent Bioscavengers Development

Directed evolution methods for overcoming trade‐offs between protein activity and stability

Optimization of Cholinesterase-Based Catalytic Bioscavengers Against Organophosphorus Agents

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