<i>De novo</i> design of a polycarbonate hydrolase

Holst, Laura H; Madsen, Niklas G; Toftgård, Freja T; Rønne, Freja; Moise, Ioana-Malina; Petersen, Evamaria I; Fojan, Peter

doi:10.1093/protein/gzad022

Protein Engineering, Design and Selection

2023

DOI: 10.1093/protein/gzad022

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De novo design of a polycarbonate hydrolase

Laura H Holst,

Niklas G Madsen,

Freja T Toftgård

et al.

Abstract: Enzymatic degradation of plastics is currently limited to the use of engineered natural enzymes. As of yet, all engineering approaches applied to plastic degrading enzymes retain the natural $\alpha /\beta $-fold. While mutations can be used to increase thermostability, an inherent maximum likely exists for the $\alpha /\beta $-fold. It is thus of interest to introduce catalytic activity toward plastics in a different protein fold to escape the sequence space of plastic degrading enzymes. Here, a method for de… Show more

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2024

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Cited by 4 publications

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Cutting-edge computational approaches in enzyme design and activity enhancement

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Albayati,

Nezhad,

Taki

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International Journal of Biological Macromolecules

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Design of a Novel Peptide with Esterolytic Activity toward PET by Mimicking the Catalytic Motif of Serine Hydrolases

Koch,

Hess,

Bak

et al. 2024

J. Phys. Chem. B

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Serine hydrolases have become increasingly important for recycling PET plastics. However, their properties are inherently constrained by their 3D structure, which in turn limits the conditions for their application. Considering peptides as catalysts for industrial depolymerization processes can help us to escape some of these limitations. In this article, a 25 amino acid thermostable peptide, HSH-25, was designed to depolymerize PET. The peptide incorporates a His–Ser–His motif, inspired by the catalytic triad found in the serine hydrolase family, into a β-hairpin fold. Stability of the fold was investigated by molecular dynamics simulations. Esterolytic activity of the peptide toward model substrates was detected within a pH range from pH 7 to pH 9.5. Degradation of polymeric PET substrates was confirmed by atomic force microscopy imaging on spin-coated PET thin films.

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De novo design of a polycarbonate hydrolase

Cited by 4 publications

References 60 publications

Cutting-edge computational approaches in enzyme design and activity enhancement

Cutting-edge computational approaches in enzyme design and activity enhancement

Efficient and easible biocatalysts: Strategies for enzyme improvement. A review

Design of a Novel Peptide with Esterolytic Activity toward PET by Mimicking the Catalytic Motif of Serine Hydrolases

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