Evolutionary Specialization of a Promiscuous Designer Enzyme

Reuben B. Leveson-Gower; Laura Tiessler-Sala; Henriette J. Rozeboom; Andy Mark W.H. Thunnissen; Jean Didier Maréchal; Gerard Roelfes

doi:10.1021/acscatal.4c06409

Evolutionary Specialization of a Promiscuous Designer Enzyme

Reuben B. Leveson-Gower^*, Laura Tiessler-Sala, Henriette J. Rozeboom, Andy Mark W.H. Thunnissen, Jean Didier Maréchal, Gerard Roelfes^*

^*Corresponding author for this work

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

Abstract

The evolution of a promiscuous enzyme for its various activities often results in catalytically specialized variants. This is an important natural mechanism to ensure the proper functioning of natural metabolic networks. It also acts as both a curse and blessing for enzyme engineers, where enzymes that have undergone directed evolution may exhibit exquisite selectivity at the expense of a diminished overall catalytic repertoire. We previously performed two independent directed evolution campaigns on a promiscuous designer enzyme that leverages the unique properties of a noncanonical amino acid (ncAA) para-aminophenylalanine (pAF) as catalytic residue, resulting in two evolved variants which are both catalytically specialized. Here, we combine mutagenesis, crystallography, and computation to reveal the molecular basis of the specialization phenomenon. In one evolved variant, an unexpected change in quaternary structure biases substrate dynamics to promote enantioselective catalysis, while the other demonstrates synergistic cooperation between natural side chains and the pAF residue to form semisynthetic catalytic machinery.

Original language	English
Pages (from-to)	1544-1552
Number of pages	9
Journal	ACS Catalysis
Volume	15
Issue number	3
Early online date	13-Jan-2025
DOIs	https://doi.org/10.1021/acscatal.4c06409
Publication status	Published - Feb-2025

Keywords

Biocatalysis
Designer Enzymes
Directed Evolution
Molecular Dynamics
Noncanonical-Amino Acids
Quantum Chemistry
X-ray Crystallography

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title = "Evolutionary Specialization of a Promiscuous Designer Enzyme",

abstract = "The evolution of a promiscuous enzyme for its various activities often results in catalytically specialized variants. This is an important natural mechanism to ensure the proper functioning of natural metabolic networks. It also acts as both a curse and blessing for enzyme engineers, where enzymes that have undergone directed evolution may exhibit exquisite selectivity at the expense of a diminished overall catalytic repertoire. We previously performed two independent directed evolution campaigns on a promiscuous designer enzyme that leverages the unique properties of a noncanonical amino acid (ncAA) para-aminophenylalanine (pAF) as catalytic residue, resulting in two evolved variants which are both catalytically specialized. Here, we combine mutagenesis, crystallography, and computation to reveal the molecular basis of the specialization phenomenon. In one evolved variant, an unexpected change in quaternary structure biases substrate dynamics to promote enantioselective catalysis, while the other demonstrates synergistic cooperation between natural side chains and the pAF residue to form semisynthetic catalytic machinery.",

keywords = "Biocatalysis, Designer Enzymes, Directed Evolution, Molecular Dynamics, Noncanonical-Amino Acids, Quantum Chemistry, X-ray Crystallography",

author = "Leveson-Gower, {Reuben B.} and Laura Tiessler-Sala and Rozeboom, {Henriette J.} and Thunnissen, {Andy Mark W.H.} and Mar{\'e}chal, {Jean Didier} and Gerard Roelfes",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society.",

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AU - Leveson-Gower, Reuben B.

AU - Tiessler-Sala, Laura

AU - Rozeboom, Henriette J.

AU - Thunnissen, Andy Mark W.H.

AU - Maréchal, Jean Didier

AU - Roelfes, Gerard

PY - 2025/2

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N2 - The evolution of a promiscuous enzyme for its various activities often results in catalytically specialized variants. This is an important natural mechanism to ensure the proper functioning of natural metabolic networks. It also acts as both a curse and blessing for enzyme engineers, where enzymes that have undergone directed evolution may exhibit exquisite selectivity at the expense of a diminished overall catalytic repertoire. We previously performed two independent directed evolution campaigns on a promiscuous designer enzyme that leverages the unique properties of a noncanonical amino acid (ncAA) para-aminophenylalanine (pAF) as catalytic residue, resulting in two evolved variants which are both catalytically specialized. Here, we combine mutagenesis, crystallography, and computation to reveal the molecular basis of the specialization phenomenon. In one evolved variant, an unexpected change in quaternary structure biases substrate dynamics to promote enantioselective catalysis, while the other demonstrates synergistic cooperation between natural side chains and the pAF residue to form semisynthetic catalytic machinery.

AB - The evolution of a promiscuous enzyme for its various activities often results in catalytically specialized variants. This is an important natural mechanism to ensure the proper functioning of natural metabolic networks. It also acts as both a curse and blessing for enzyme engineers, where enzymes that have undergone directed evolution may exhibit exquisite selectivity at the expense of a diminished overall catalytic repertoire. We previously performed two independent directed evolution campaigns on a promiscuous designer enzyme that leverages the unique properties of a noncanonical amino acid (ncAA) para-aminophenylalanine (pAF) as catalytic residue, resulting in two evolved variants which are both catalytically specialized. Here, we combine mutagenesis, crystallography, and computation to reveal the molecular basis of the specialization phenomenon. In one evolved variant, an unexpected change in quaternary structure biases substrate dynamics to promote enantioselective catalysis, while the other demonstrates synergistic cooperation between natural side chains and the pAF residue to form semisynthetic catalytic machinery.

KW - Biocatalysis

KW - Designer Enzymes

KW - Directed Evolution

KW - Molecular Dynamics

KW - Noncanonical-Amino Acids

KW - Quantum Chemistry

KW - X-ray Crystallography

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Evolutionary Specialization of a Promiscuous Designer Enzyme

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