Transition State-Based Computational Enzyme Design

Thomas Gaillard; Thomas Simonson

doi:10.1007/978-1-0716-4828-5_11

Transition State-Based Computational Enzyme Design

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Our approach to computational protein design is physics-based. We develop a software called Proteus, allowing both physics-based energy evaluation and sequence-conformation exploration. Unlike knowledge-based models, a physics-based energy function facilitates the consideration of unusual chemical entities, such as novel ligands or transition states. Additionally, the adaptive landscape flattening method allows direct sampling on free energy difference between two states. We show here how these ingredients combined can benefit enzyme design. As an illustration, we revisit the stereospecificity inversion of tyrosyl-tRNA synthetase. Following a tutorial presentation, we explore various design criteria that can be related to enzyme experimental parameters. Our model is able to retrieve the native sequence when targeting L-tyrosine. Mutations predicted to favor D-tyrosine are proposed.

Original language	English
Title of host publication	Methods in Molecular Biology
Publisher	Humana Press Inc.
Pages	165-186
Number of pages	22
DOIs	https://doi.org/10.1007/978-1-0716-4828-5_11
Publication status	Published - 1 Jan 2026

Publication series

Name	Methods in Molecular Biology
Volume	2979
ISSN (Print)	1064-3745
ISSN (Electronic)	1940-6029

Keywords

Aminoacyl-tRNA synthetase
CPD
D-amino acid
Design
Enzyme
Protein
Sequence
Transition state

Access to Document

10.1007/978-1-0716-4828-5_11

Cite this

@inbook{1bdcf641743a434d9312cc65a11c95af,

title = "Transition State-Based Computational Enzyme Design",

abstract = "Our approach to computational protein design is physics-based. We develop a software called Proteus, allowing both physics-based energy evaluation and sequence-conformation exploration. Unlike knowledge-based models, a physics-based energy function facilitates the consideration of unusual chemical entities, such as novel ligands or transition states. Additionally, the adaptive landscape flattening method allows direct sampling on free energy difference between two states. We show here how these ingredients combined can benefit enzyme design. As an illustration, we revisit the stereospecificity inversion of tyrosyl-tRNA synthetase. Following a tutorial presentation, we explore various design criteria that can be related to enzyme experimental parameters. Our model is able to retrieve the native sequence when targeting L-tyrosine. Mutations predicted to favor D-tyrosine are proposed.",

keywords = "Aminoacyl-tRNA synthetase, CPD, D-amino acid, Design, Enzyme, Protein, Sequence, Transition state",

author = "Thomas Gaillard and Thomas Simonson",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature 2026.",

year = "2026",

month = jan,

day = "1",

doi = "10.1007/978-1-0716-4828-5\_11",

language = "English",

series = "Methods in Molecular Biology",

publisher = "Humana Press Inc.",

pages = "165--186",

booktitle = "Methods in Molecular Biology",

}

TY - CHAP

T1 - Transition State-Based Computational Enzyme Design

AU - Gaillard, Thomas

AU - Simonson, Thomas

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature 2026.

PY - 2026/1/1

Y1 - 2026/1/1

N2 - Our approach to computational protein design is physics-based. We develop a software called Proteus, allowing both physics-based energy evaluation and sequence-conformation exploration. Unlike knowledge-based models, a physics-based energy function facilitates the consideration of unusual chemical entities, such as novel ligands or transition states. Additionally, the adaptive landscape flattening method allows direct sampling on free energy difference between two states. We show here how these ingredients combined can benefit enzyme design. As an illustration, we revisit the stereospecificity inversion of tyrosyl-tRNA synthetase. Following a tutorial presentation, we explore various design criteria that can be related to enzyme experimental parameters. Our model is able to retrieve the native sequence when targeting L-tyrosine. Mutations predicted to favor D-tyrosine are proposed.

AB - Our approach to computational protein design is physics-based. We develop a software called Proteus, allowing both physics-based energy evaluation and sequence-conformation exploration. Unlike knowledge-based models, a physics-based energy function facilitates the consideration of unusual chemical entities, such as novel ligands or transition states. Additionally, the adaptive landscape flattening method allows direct sampling on free energy difference between two states. We show here how these ingredients combined can benefit enzyme design. As an illustration, we revisit the stereospecificity inversion of tyrosyl-tRNA synthetase. Following a tutorial presentation, we explore various design criteria that can be related to enzyme experimental parameters. Our model is able to retrieve the native sequence when targeting L-tyrosine. Mutations predicted to favor D-tyrosine are proposed.

KW - Aminoacyl-tRNA synthetase

KW - CPD

KW - D-amino acid

KW - Design

KW - Enzyme

KW - Protein

KW - Sequence

KW - Transition state

UR - https://www.scopus.com/pages/publications/105020652333

U2 - 10.1007/978-1-0716-4828-5_11

DO - 10.1007/978-1-0716-4828-5_11

M3 - Chapter

C2 - 41174313

AN - SCOPUS:105020652333

T3 - Methods in Molecular Biology

SP - 165

EP - 186

BT - Methods in Molecular Biology

PB - Humana Press Inc.

ER -

Transition State-Based Computational Enzyme Design

Abstract

Publication series

Keywords

Access to Document

Other files and links

Fingerprint

Cite this