Robust deep learning–based protein sequence design using ProteinMPNN

Justas Dauparas; Ivan Anishchenko; Nathaniel R. Bennett; Hua Bai; Robert J. Ragotte; Lukas F. Milles; Basile I. M. Wicky; Alexis Courbet; Robbert J. de Haas; Neville P. Bethel; Philip J. Y. Leung; Timothy F. Huddy; Samuel J. Pellock; Doug Tischer; F. Chan; Brian Koepnick; Hannah Nguyen; Alex Kang; Banumathi Sankaran; Asim K. Bera; Neil P. King; David Baker

doi:10.1126/science.add2187

Robust deep learning–based protein sequence design using ProteinMPNN

Justas Dauparas(University of Washington), Ivan Anishchenko(University of Washington), Nathaniel R. Bennett(University of Washington), Hua Bai(Howard Hughes Medical Institute), Robert J. Ragotte(University of Washington), Lukas F. Milles(University of Washington), Basile I. M. Wicky(University of Washington), Alexis Courbet(Howard Hughes Medical Institute), Robbert J. de Haas(Wageningen University & Research), Neville P. Bethel(Howard Hughes Medical Institute), Philip J. Y. Leung(University of Washington), Timothy F. Huddy(University of Washington), Samuel J. Pellock(University of Washington), Doug Tischer(University of Washington), F. Chan(University of Washington), Brian Koepnick(University of Washington), Hannah Nguyen(University of Washington), Alex Kang(University of Washington), Banumathi Sankaran(Lawrence Berkeley National Laboratory), Asim K. Bera(University of Washington), Neil P. King(University of Washington), David Baker(Howard Hughes Medical Institute)

Science

September 15, 2022

10.1126/science.add2187

Cited by 1,776Open Access

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Abstract

Although deep learning has revolutionized protein structure prediction, almost all experimentally characterized de novo protein designs have been generated using physically based approaches such as Rosetta. Here, we describe a deep learning-based protein sequence design method, ProteinMPNN, that has outstanding performance in both in silico and experimental tests. On native protein backbones, ProteinMPNN has a sequence recovery of 52.4% compared with 32.9% for Rosetta. The amino acid sequence at different positions can be coupled between single or multiple chains, enabling application to a wide range of current protein design challenges. We demonstrate the broad utility and high accuracy of ProteinMPNN using x-ray crystallography, cryo-electron microscopy, and functional studies by rescuing previously failed designs, which were made using Rosetta or AlphaFold, of protein monomers, cyclic homo-oligomers, tetrahedral nanoparticles, and target-binding proteins.

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