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Therapeutic enzyme engineering using a generative neural network

Andrew J. Giessel, Athanasios Dousis, Kanchana Ravichandran, Kevin Smith, Sreyoshi Sur, Iain J. McFadyen, Wei Zheng, Stuart Licht

2022Scientific Reports46 citationsDOIOpen Access PDF

Abstract

Enhancing the potency of mRNA therapeutics is an important objective for treating rare diseases, since it may enable lower and less-frequent dosing. Enzyme engineering can increase potency of mRNA therapeutics by improving the expression, half-life, and catalytic efficiency of the mRNA-encoded enzymes. However, sequence space is incomprehensibly vast, and methods to map sequence to function (computationally or experimentally) are inaccurate or time-/labor-intensive. Here, we present a novel, broadly applicable engineering method that combines deep latent variable modelling of sequence co-evolution with automated protein library design and construction to rapidly identify metabolic enzyme variants that are both more thermally stable and more catalytically active. We apply this approach to improve the potency of ornithine transcarbamylase (OTC), a urea cycle enzyme for which loss of catalytic activity causes a rare but serious metabolic disease.

Topics & Concepts

Urea cyclePotencyEnzymeComputational biologySequence (biology)Messenger RNAFunction (biology)Drug discoveryBiochemistryComputer scienceBioinformaticsBiologyIn vitroCell biologyGeneAmino acidArginineBiochemical and Molecular ResearchEnzyme Structure and FunctionAmino Acid Enzymes and Metabolism
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