De novo design of protein logic gates

Zibo Chen(University of Washington), Ryan D. Kibler(University of Washington), Andrew C. Hunt(Northwestern University), Florian Büsch(The Ohio State University), Jocelynn R. Pearl(Altius Institute for Biomedical Sciences), Mengxuan Jia(The Ohio State University), Zachary L. VanAernum(The Ohio State University), Basile I. M. Wicky(University of Washington), Galen Dods(University of California, San Francisco), Hanna Liao(Altius Institute for Biomedical Sciences), Matthew S. Wilken(Altius Institute for Biomedical Sciences), Christie Ciarlo(Altius Institute for Biomedical Sciences), Shon Green(Altius Institute for Biomedical Sciences), Hana El‐Samad(University of California, San Francisco), J Stamatoyannopoulos(University of Washington), Vicki H. Wysocki(The Ohio State University), Michael C. Jewett(Northwestern University), Scott E. Boyken(University of Washington), David Baker(Howard Hughes Medical Institute)
Science
April 2, 2020
10.1126/science.aay2790
Cited by 223Open Access
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Abstract

Designer gates Signaling in cells can occur through protein-protein interactions. Chen et al. describe the design of logic gates that can regulate protein association. The gates were built from small, designed proteins that all have a similar structure but where one module can be designed to interact specifically with another module. Using monomers and covalently connected monomers as inputs and encoding specificity through designed hydrogen-bond networks allowed the construction of two-input or three-input gates based on competitive binding. The modular control elements were used to regulate the association of elements of transcription machinery and split enzymes in vitro and in yeast cells. Science , this issue p. 78

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