Simultaneous enhancement of multiple functional properties using evolution-informed protein design.

Publication Type:

Journal Article

Source:

Nat Commun, Volume 15, Issue 1, p.5141 (2024)

Keywords:

Amino Acid Sequence, beta-Lactamases, Enzyme Stability, Evolution, Molecular, Models, Molecular, Mutation, Protein Conformation, Protein Engineering

Abstract:

<p>A major challenge in protein design is to augment existing functional proteins with multiple property enhancements. Altering several properties likely necessitates numerous primary sequence changes, and novel methods are needed to accurately predict combinations of mutations that maintain or enhance function. Models of sequence co-variation (e.g., EVcouplings), which leverage extensive information about various protein properties and activities from homologous protein sequences, have proven effective for many applications including structure determination and mutation effect prediction. We apply EVcouplings to computationally design variants of the model protein TEM-1 β-lactamase. Nearly all the 14 experimentally characterized designs were functional, including one with 84 mutations from the nearest natural homolog. The designs also had large increases in thermostability, increased activity on multiple substrates, and nearly identical structure to the wild type enzyme. This study highlights the efficacy of evolutionary models in guiding large sequence alterations to generate functional diversity for protein design applications.</p>

PDB: 
The crystal structures generated in this study have been deposited in the RCSB Protein Data Bank (RCSB PDB) under accession codes 8RQU [10.2210/pdb8RQU/pdb] (70.a), 8GII [10.2210/pdb8GII/pdb] (80.a), and 8GIJ [10.2210/pdb8GIJ/pdb] (80.b).
Detector: 
EIGER
Beamline: 
24-ID-C