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Tailoring industrial enzymes for thermostability and activity evolution by the machine learning-based iCASE strategy

Nan Zheng, Yongchao Cai, Zehua Zhang, Huimin Zhou, Yu Deng, Shuang Du, Mengting Tu, Fang Wei, Xiaole Xia

2025Nature Communications57 citationsDOIOpen Access PDF

Abstract

The pursuit of obtaining enzymes with high activity and stability remains a grail in enzyme evolution due to the stability-activity trade-off. Here, we develop an isothermal compressibility-assisted dynamic squeezing index perturbation engineering (iCASE) strategy to construct hierarchical modular networks for enzymes of varying complexity. Molecular mechanism analysis elucidates that the peak of adaptive evolution is reached through a structural response mechanism among variants. Furthermore, this dynamic response predictive model using structure-based supervised machine learning is established to predict enzyme function and fitness, demonstrating robust performance across different datasets and reliable prediction for epistasis. The universality of the iCASE strategy is validated by four sorts of enzymes with different structures and catalytic types. This machine learning-based iCASE strategy provides guidance for future research on the fitness evolution of enzymes. The authors design an isothermal compressibility-assisted dynamic squeezing index perturbation (iCASE) methodology to improve enzyme stability and efficacy, which is combined with machine learning predictive models to advance enzyme optimization.

Topics & Concepts

ThermostabilityBiochemical engineeringEnzymeComputational biologyComputer scienceBiologyBiochemistryEngineeringMicrobial Metabolic Engineering and BioproductionEnzyme Catalysis and ImmobilizationProtein Structure and Dynamics