Binding and sensing diverse small molecules using shape-complementary pseudocycles

Linna An; Meerit Y. Said; Long Tran; Sagardip Majumder; Inna Goreshnik; Gyu Rie Lee; David Juergens; Justas Dauparas; Ivan Anishchenko; Brian Coventry; Asim K. Bera; Alex Kang; Paul M. Levine; Valentina González Álvarez; Arvind Pillai; Christoffer Norn; David Feldman; Dmitri Zorine; Derrick R. Hicks; Xinting Li; M. SANCHEZ; Dionne Vafeados; Patrick J. Salveson; Anastassia A. Vorobieva; David Baker

doi:10.1126/science.adn3780

Binding and sensing diverse small molecules using shape-complementary pseudocycles

Linna An(University of Washington), Meerit Y. Said(University of Washington), Long Tran(University of Washington), Sagardip Majumder(University of Washington), Inna Goreshnik(University of Washington), Gyu Rie Lee(University of Washington), David Juergens(University of Washington), Justas Dauparas(University of Washington), Ivan Anishchenko(University of Washington), Brian Coventry(Howard Hughes Medical Institute), Asim K. Bera(University of Washington), Alex Kang(University of Washington), Paul M. Levine(University of Washington), Valentina González Álvarez(University of Washington), Arvind Pillai(University of Washington), Christoffer Norn(BioInnovation Institute), David Feldman(BioInnovation Institute), Dmitri Zorine(University of Washington), Derrick R. Hicks(University of Washington), Xinting Li(University of Washington), M. SANCHEZ(University of Washington), Dionne Vafeados(University of Washington), Patrick J. Salveson(University of Washington), Anastassia A. Vorobieva(Vrije Universiteit Brussel), David Baker(University of Washington)

Science

July 18, 2024

10.1126/science.adn3780

Cited by 76Open Access

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Abstract

We describe an approach for designing high-affinity small molecule-binding proteins poised for downstream sensing. We use deep learning-generated pseudocycles with repeating structural units surrounding central binding pockets with widely varying shapes that depend on the geometry and number of the repeat units. We dock small molecules of interest into the most shape complementary of these pseudocycles, design the interaction surfaces for high binding affinity, and experimentally screen to identify designs with the highest affinity. We obtain binders to four diverse molecules, including the polar and flexible methotrexate and thyroxine. Taking advantage of the modular repeat structure and central binding pockets, we construct chemically induced dimerization systems and low-noise nanopore sensors by splitting designs into domains that reassemble upon ligand addition.

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