A Bioengineered Stable Protein 1-Hemin Complex with Enhanced Peroxidase-Like Catalytic Properties

Yara Zeibaq; Oren Bachar; Jenia Sklyar; Noam Adir; Omer Yehezkeli

doi:10.1002/smsc.202400025

A Bioengineered Stable Protein 1-Hemin Complex with Enhanced Peroxidase-Like Catalytic Properties

Yara Zeibaq, Oren Bachar, Jenia Sklyar, Noam Adir, Omer Yehezkeli

Research output: Contribution to journal › Article › peer-review

Abstract

Enzymes have gained their unique efficiency and catalytic activity through billions of years of evolution, perfecting their active site to a desired reaction. Inspired by nature, a novel enzyme-mimicking platform is designed based on stable protein 1 (SP1) to create a nano-compartment that mimics peroxidase activity. The biohybrid reveals enhanced activity over the hemin cofactor alone and improved stability in organic solvents in comparison to native peroxidase. Furthermore, the utilization of the obtained biohybrid in an optical glucose biosensing platform is shown. The biohybrid crystallographic structure is solved, indicating that the SP1 structure is not affected by the hemin coordination. This work opens the path for developing new cofactor binding centers in engineered protein scaffolds for various artificial catalytic processes.

Original language	English
Journal	Small Science
DOIs	https://doi.org/10.1002/smsc.202400025
State	Accepted/In press - 2024

Keywords

artificial enzyme
biocatalysis
glucose biosensing
peroxidase
stable protein 1

ASJC Scopus subject areas

Catalysis
Chemical Engineering (miscellaneous)
Materials Science (miscellaneous)

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10.1002/smsc.202400025

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title = "A Bioengineered Stable Protein 1-Hemin Complex with Enhanced Peroxidase-Like Catalytic Properties",

abstract = "Enzymes have gained their unique efficiency and catalytic activity through billions of years of evolution, perfecting their active site to a desired reaction. Inspired by nature, a novel enzyme-mimicking platform is designed based on stable protein 1 (SP1) to create a nano-compartment that mimics peroxidase activity. The biohybrid reveals enhanced activity over the hemin cofactor alone and improved stability in organic solvents in comparison to native peroxidase. Furthermore, the utilization of the obtained biohybrid in an optical glucose biosensing platform is shown. The biohybrid crystallographic structure is solved, indicating that the SP1 structure is not affected by the hemin coordination. This work opens the path for developing new cofactor binding centers in engineered protein scaffolds for various artificial catalytic processes.",

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doi = "10.1002/smsc.202400025",

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T1 - A Bioengineered Stable Protein 1-Hemin Complex with Enhanced Peroxidase-Like Catalytic Properties

AU - Zeibaq, Yara

AU - Bachar, Oren

AU - Sklyar, Jenia

AU - Adir, Noam

AU - Yehezkeli, Omer

PY - 2024

Y1 - 2024

N2 - Enzymes have gained their unique efficiency and catalytic activity through billions of years of evolution, perfecting their active site to a desired reaction. Inspired by nature, a novel enzyme-mimicking platform is designed based on stable protein 1 (SP1) to create a nano-compartment that mimics peroxidase activity. The biohybrid reveals enhanced activity over the hemin cofactor alone and improved stability in organic solvents in comparison to native peroxidase. Furthermore, the utilization of the obtained biohybrid in an optical glucose biosensing platform is shown. The biohybrid crystallographic structure is solved, indicating that the SP1 structure is not affected by the hemin coordination. This work opens the path for developing new cofactor binding centers in engineered protein scaffolds for various artificial catalytic processes.

AB - Enzymes have gained their unique efficiency and catalytic activity through billions of years of evolution, perfecting their active site to a desired reaction. Inspired by nature, a novel enzyme-mimicking platform is designed based on stable protein 1 (SP1) to create a nano-compartment that mimics peroxidase activity. The biohybrid reveals enhanced activity over the hemin cofactor alone and improved stability in organic solvents in comparison to native peroxidase. Furthermore, the utilization of the obtained biohybrid in an optical glucose biosensing platform is shown. The biohybrid crystallographic structure is solved, indicating that the SP1 structure is not affected by the hemin coordination. This work opens the path for developing new cofactor binding centers in engineered protein scaffolds for various artificial catalytic processes.

KW - artificial enzyme

KW - biocatalysis

KW - glucose biosensing

KW - peroxidase

KW - stable protein 1

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A Bioengineered Stable Protein 1-Hemin Complex with Enhanced Peroxidase-Like Catalytic Properties

Abstract

Keywords

ASJC Scopus subject areas

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