Improving de novo protein binder design with deep learning

Nathaniel R. Bennett; Brian Coventry; Inna Goreshnik; Buwei Huang; Aza Allen; Dionne Vafeados; Ying Po Peng; Justas Dauparas; Minkyung Baek; Lance Stewart; Frank DiMaio; Steven De Munck; Savvas N. Savvides; David Baker

doi:10.1038/s41467-023-38328-5

Improving de novo protein binder design with deep learning

Nathaniel R. Bennett(University of Washington), Brian Coventry(Howard Hughes Medical Institute), Inna Goreshnik(University of Washington), Buwei Huang(University of Washington), Aza Allen(University of Washington), Dionne Vafeados(University of Washington), Ying Po Peng(University of Washington), Justas Dauparas(University of Washington), Minkyung Baek(University of Washington), Lance Stewart(University of Washington), Frank DiMaio(University of Washington), Steven De Munck(Ghent University), Savvas N. Savvides(Ghent University), David Baker(Howard Hughes Medical Institute)

Nature Communications

May 6, 2023

10.1038/s41467-023-38328-5

Cited by 353Open Access

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Abstract

Recently it has become possible to de novo design high affinity protein binding proteins from target structural information alone. There is, however, considerable room for improvement as the overall design success rate is low. Here, we explore the augmentation of energy-based protein binder design using deep learning. We find that using AlphaFold2 or RoseTTAFold to assess the probability that a designed sequence adopts the designed monomer structure, and the probability that this structure binds the target as designed, increases design success rates nearly 10-fold. We find further that sequence design using ProteinMPNN rather than Rosetta considerably increases computational efficiency.

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