Abstract
Protein stability plays a crucial role in a variety of applications, such as food processing, therapeutics, and the identification of pathogenic mutations. Engineering campaigns commonly seek to improve protein stability, and there is a strong interest in streamlining these processes to enable rapid optimization of highly stabilized proteins with fewer iterations. In this work, we explore utilizing a mega-scale dataset to develop a protein language model optimized for stability prediction. ESMtherm is trained on the folding stability of 528k natural and de novo sequences derived from 461 protein domains and can accommodate deletions, insertions, and multiple-point mutations. We show that a protein language model can be fine-tuned to predict folding stability. ESMtherm performs reasonably on small protein domains and generalizes to sequences distal from the training set. Lastly, we discuss our model’s limitations compared to other state-of-the-art methods in generalizing to larger protein scaffolds. Our results highlight the need for large-scale stability measurements on a diverse dataset that mirrors the distribution of sequence lengths commonly observed in nature.
Publisher
Public Library of Science (PLoS)
Reference58 articles.
1. Enhancing the Thermal and Kinetic Stability of Ketol-Acid Reductoisomerase, a Central Catalyst of a Cell-Free Enzyme Cascade for the Manufacture of Platform Chemicals;Y. Lv;Applied Biosciences
2. Rational Protein Engineering to Increase the Activity and Stability of IsPETase Using the PROSS Algorithm;A. Rennison;Polymers
3. Enhancement of antibody thermostability and affinity by computational design in the absence of antigen;M. Hutchinson;bioRxiv,2023
4. Identification of pathogenic missense mutations using protein stability predictors;L. Gerasimavicius;Scientific Reports,2020
5. Accurate proteome-wide missense variant effect prediction with AlphaMissense;J. Cheng;Science,2023