Electrostatics As a Guiding Principle in Understanding and Designing Enzymes

Overview

Journal J Chem Theory Comput

Publisher American Chemical Society

Specialties Biochemistry
Chemistry

Date 2024 Feb 27

PMID 38410913

Authors

J Javier Ruiz-Pernia

Katarzyna Swiderek

Joan Bertran

Vicent Moliner

Inaki Tunon

Affiliations

Soon will be listed here.

Abstract

Enzyme design faces challenges related to the implementation of the basic principles that govern the catalytic activity in natural enzymes. In this work, we revisit basic electrostatic concepts that have been shown to explain the origin of enzymatic efficiency like preorganization and reorganization. Using magnitudes such as the electrostatic potential and the electric field generated by the protein, we explain how these concepts work in different enzymes and how they can be used to rationalize the consequences of point mutations. We also discuss examples of protein design in which electrostatic effects have been implemented. For the near future, molecular simulations, coupled with the use of machine learning methods, can be used to implement electrostatics as a guiding principle for enzyme designs.

Citing Articles

Long-Range Electrostatics in Serine Proteases: Machine Learning-Driven Reaction Sampling Yields Insights for Enzyme Design.

Zlobin A, Maslova V, Beliaeva J, Meiler J, Golovin A J Chem Inf Model. 2025; 65(4):2003-2013.

PMID: 39928564 PMC: 11863386. DOI: 10.1021/acs.jcim.4c01827.

Electrostatic Preorganization in Three Distinct Heterogeneous Proteasome β-Subunits.

Ferrer S, Moliner V, Swiderek K ACS Catal. 2024; 14(20):15237-15249.

PMID: 39444531 PMC: 11494509. DOI: 10.1021/acscatal.4c04964.

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