Reversible peptide tagging system to regulate enzyme activity

Yao Chen; Yi Shi; Dengming Ming; He Huang; Ling Jiang

doi:10.1016/j.xcrp.2025.102462

Reversible peptide tagging system to regulate enzyme activity

Yao Chen, Yi Shi, Dengming Ming, He Huang, Ling Jiang

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摘要

Peptide tagging systems are widely used across scientific fields. Here, to obtain a peptide tagging system with high covalent linkage efficiency, we rationally designed the ReverseTag/ReverseCatcher system, building upon the ester-bond-based peptide tagging system Cpe0147⁴³⁹⁻⁵⁶³/Cpe0147^565−587. Our optimized system exhibits a second-order rate constant of 1.92 ± 0.002 × 10⁴ M⁻¹ s⁻¹, a 21.7-fold increase over the wild-type system. The ester bond between ReverseTag and ReverseCatcher demonstrates exceptional mechanical stability, withstanding forces over 2 nN, while remaining hydrolyzable under alkaline conditions with significant energy input. To leverage this for enzymatic catalysis, we introduced a T11S mutation into ReverseCatcher, allowing pH-controlled reversible bond formation and cleavage. Applying this strategy to exo-inulinase (EXINU) enables precise, pH-dependent enzyme activity control. This sustainable method for modulating enzyme-catalyzed reactions offers broad biotechnological potential.

源语言	英语
文章编号	102462
期刊	Cell Reports Physical Science
卷	6
期	3
DOI	https://doi.org/10.1016/j.xcrp.2025.102462
出版状态	已出版 - 19 3月 2025

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title = "Reversible peptide tagging system to regulate enzyme activity",

abstract = "Peptide tagging systems are widely used across scientific fields. Here, to obtain a peptide tagging system with high covalent linkage efficiency, we rationally designed the ReverseTag/ReverseCatcher system, building upon the ester-bond-based peptide tagging system Cpe0147439−563/Cpe0147565−587. Our optimized system exhibits a second-order rate constant of 1.92 ± 0.002 × 104 M−1 s−1, a 21.7-fold increase over the wild-type system. The ester bond between ReverseTag and ReverseCatcher demonstrates exceptional mechanical stability, withstanding forces over 2 nN, while remaining hydrolyzable under alkaline conditions with significant energy input. To leverage this for enzymatic catalysis, we introduced a T11S mutation into ReverseCatcher, allowing pH-controlled reversible bond formation and cleavage. Applying this strategy to exo-inulinase (EXINU) enables precise, pH-dependent enzyme activity control. This sustainable method for modulating enzyme-catalyzed reactions offers broad biotechnological potential.",

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author = "Yao Chen and Yi Shi and Dengming Ming and He Huang and Ling Jiang",

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T1 - Reversible peptide tagging system to regulate enzyme activity

AU - Chen, Yao

AU - Shi, Yi

AU - Ming, Dengming

AU - Huang, He

AU - Jiang, Ling

PY - 2025/3/19

Y1 - 2025/3/19

N2 - Peptide tagging systems are widely used across scientific fields. Here, to obtain a peptide tagging system with high covalent linkage efficiency, we rationally designed the ReverseTag/ReverseCatcher system, building upon the ester-bond-based peptide tagging system Cpe0147439−563/Cpe0147565−587. Our optimized system exhibits a second-order rate constant of 1.92 ± 0.002 × 104 M−1 s−1, a 21.7-fold increase over the wild-type system. The ester bond between ReverseTag and ReverseCatcher demonstrates exceptional mechanical stability, withstanding forces over 2 nN, while remaining hydrolyzable under alkaline conditions with significant energy input. To leverage this for enzymatic catalysis, we introduced a T11S mutation into ReverseCatcher, allowing pH-controlled reversible bond formation and cleavage. Applying this strategy to exo-inulinase (EXINU) enables precise, pH-dependent enzyme activity control. This sustainable method for modulating enzyme-catalyzed reactions offers broad biotechnological potential.

AB - Peptide tagging systems are widely used across scientific fields. Here, to obtain a peptide tagging system with high covalent linkage efficiency, we rationally designed the ReverseTag/ReverseCatcher system, building upon the ester-bond-based peptide tagging system Cpe0147439−563/Cpe0147565−587. Our optimized system exhibits a second-order rate constant of 1.92 ± 0.002 × 104 M−1 s−1, a 21.7-fold increase over the wild-type system. The ester bond between ReverseTag and ReverseCatcher demonstrates exceptional mechanical stability, withstanding forces over 2 nN, while remaining hydrolyzable under alkaline conditions with significant energy input. To leverage this for enzymatic catalysis, we introduced a T11S mutation into ReverseCatcher, allowing pH-controlled reversible bond formation and cleavage. Applying this strategy to exo-inulinase (EXINU) enables precise, pH-dependent enzyme activity control. This sustainable method for modulating enzyme-catalyzed reactions offers broad biotechnological potential.

KW - enzyme activity regulation

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JO - Cell Reports Physical Science

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Reversible peptide tagging system to regulate enzyme activity

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