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Unsupervised evolution of protein and antibody complexes with a structure-informed language model

Varun R. Shanker, Theodora U. J. Bruun, Brian Hie, Peter S. Kim

2024Science134 citationsDOIOpen Access PDF

Abstract

Large language models trained on sequence information alone can learn high-level principles of protein design. However, beyond sequence, the three-dimensional structures of proteins determine their specific function, activity, and evolvability. Here, we show that a general protein language model augmented with protein structure backbone coordinates can guide evolution for diverse proteins without the need to model individual functional tasks. We also demonstrate that ESM-IF1, which was only trained on single-chain structures, can be extended to engineer protein complexes. Using this approach, we screened about 30 variants of two therapeutic clinical antibodies used to treat severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. We achieved up to 25-fold improvement in neutralization and 37-fold improvement in affinity against antibody-escaped viral variants of concern BQ.1.1 and XBB.1.5, respectively. These findings highlight the advantage of integrating structural information to identify efficient protein evolution trajectories without requiring any task-specific training data.

Topics & Concepts

Computational biologyEvolvabilityComputer scienceProtein structureSevere acute respiratory syndrome coronavirus 2 (SARS-CoV-2)Sequence (biology)AntibodyProtein sequencingProtein designCoronavirus disease 2019 (COVID-19)Protein engineeringFunction (biology)Artificial intelligencePeptide sequenceBiologyGeneMedicineImmunologyGeneticsBiochemistryEnzymeDiseasePathologyInfectious disease (medical specialty)RNA and protein synthesis mechanismsvaccines and immunoinformatics approachesProtein Structure and Dynamics
Unsupervised evolution of protein and antibody complexes with a structure-informed language model | Litcius