Accurate de novo design of high-affinity protein-binding macrocycles using deep learning

Stephen A. Rettie; David Juergens; Victor Adebomi; Yensi Flores Bueso; Qinqin Zhao; Alexandria N. Leveille; Andi Liu; Asim K. Bera; Joana A. Wilms; Alina Üffing; Alex Kang; Evans Brackenbrough; Mila Lamb; Stacey R. Gerben; Analisa Murray; Paul M. Levine; Maika Schneider; Vibha Vasireddy; Sergey Ovchinnikov; Oliver H. Weiergräber; Dieter Willbold; Joshua A. Kritzer; Joseph D. Mougous; David Baker; Frank DiMaio; Gaurav Bhardwaj

doi:10.1038/s41589-025-01929-w

Accurate de novo design of high-affinity protein-binding macrocycles using deep learning

Stephen A. Rettie
, David Juergens
, Victor Adebomi
, Yensi Flores Bueso
, Qinqin Zhao
, Alexandria N. Leveille
, Andi Liu
, Asim K. Bera
, Joana A. Wilms
, Alina Üffing
, Alex Kang
, Evans Brackenbrough
, Mila Lamb
, Stacey R. Gerben
, Analisa Murray
, Paul M. Levine
, Maika Schneider
, Vibha Vasireddy
, Sergey Ovchinnikov
, Oliver H. Weiergräber

Dieter Willbold, Joshua A. Kritzer, Joseph D. Mougous, David Baker, Frank DiMaio, Gaurav Bhardwaj

University of Washington
Tufts University
Heinrich Heine University Düsseldorf
Jülich Research Centre
The Francis Crick Institute
Massachusetts Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Developing macrocyclic binders to therapeutic proteins typically relies on large-scale screening methods that are resource intensive and provide little control over binding mode. Despite progress in protein design, there are currently no robust approaches for de novo design of protein-binding macrocycles. Here we introduce RFpeptides, a denoising diffusion-based pipeline for designing macrocyclic binders against protein targets of interest. We tested 20 or fewer designed macrocycles against each of four diverse proteins and obtained binders with medium to high affinity against all targets. For one of the targets, Rhombotarget A (RbtA), we designed a high-affinity binder (K_d < 10 nM) despite starting from the predicted target structure. X-ray structures for macrocycle-bound myeloid cell leukemia 1, γ-aminobutyric acid type A receptor-associated protein and RbtA complexes match closely with the computational models, with a Cα root-mean-square deviation < 1.5 Å to the design models. RFpeptides provides a framework for rapid and custom design of macrocyclic peptides for diagnostic and therapeutic applications. (Figure presented.)

Original language	English
Journal	Nature Chemical Biology
DOIs	https://doi.org/10.1038/s41589-025-01929-w
Publication status	Accepted/In press - 2025

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

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10.1038/s41589-025-01929-w

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Rettie, S. A., Juergens, D., Adebomi, V., Bueso, Y. F., Zhao, Q., Leveille, A. N., Liu, A., Bera, A. K., Wilms, J. A., Üffing, A., Kang, A., Brackenbrough, E., Lamb, M., Gerben, S. R., Murray, A., Levine, P. M., Schneider, M., Vasireddy, V., Ovchinnikov, S., ... Bhardwaj, G. (Accepted/In press). Accurate de novo design of high-affinity protein-binding macrocycles using deep learning. Nature Chemical Biology. https://doi.org/10.1038/s41589-025-01929-w

@article{5013488710984556b2937e93281729c6,

title = "Accurate de novo design of high-affinity protein-binding macrocycles using deep learning",

abstract = "Developing macrocyclic binders to therapeutic proteins typically relies on large-scale screening methods that are resource intensive and provide little control over binding mode. Despite progress in protein design, there are currently no robust approaches for de novo design of protein-binding macrocycles. Here we introduce RFpeptides, a denoising diffusion-based pipeline for designing macrocyclic binders against protein targets of interest. We tested 20 or fewer designed macrocycles against each of four diverse proteins and obtained binders with medium to high affinity against all targets. For one of the targets, Rhombotarget A (RbtA), we designed a high-affinity binder (Kd < 10 nM) despite starting from the predicted target structure. X-ray structures for macrocycle-bound myeloid cell leukemia 1, γ-aminobutyric acid type A receptor-associated protein and RbtA complexes match closely with the computational models, with a Cα root-mean-square deviation < 1.5 {\AA} to the design models. RFpeptides provides a framework for rapid and custom design of macrocyclic peptides for diagnostic and therapeutic applications. (Figure presented.)",

author = "Rettie, \{Stephen A.\} and David Juergens and Victor Adebomi and Bueso, \{Yensi Flores\} and Qinqin Zhao and Leveille, \{Alexandria N.\} and Andi Liu and Bera, \{Asim K.\} and Wilms, \{Joana A.\} and Alina {\"U}ffing and Alex Kang and Evans Brackenbrough and Mila Lamb and Gerben, \{Stacey R.\} and Analisa Murray and Levine, \{Paul M.\} and Maika Schneider and Vibha Vasireddy and Sergey Ovchinnikov and Weiergr{\"a}ber, \{Oliver H.\} and Dieter Willbold and Kritzer, \{Joshua A.\} and Mougous, \{Joseph D.\} and David Baker and Frank DiMaio and Gaurav Bhardwaj",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

doi = "10.1038/s41589-025-01929-w",

language = "English",

journal = "Nature Chemical Biology",

issn = "1552-4450",

publisher = "Nature Research",

}

Rettie, SA, Juergens, D, Adebomi, V, Bueso, YF, Zhao, Q, Leveille, AN, Liu, A, Bera, AK, Wilms, JA, Üffing, A, Kang, A, Brackenbrough, E, Lamb, M, Gerben, SR, Murray, A, Levine, PM, Schneider, M, Vasireddy, V, Ovchinnikov, S, Weiergräber, OH, Willbold, D, Kritzer, JA, Mougous, JD, Baker, D, DiMaio, F & Bhardwaj, G 2025, 'Accurate de novo design of high-affinity protein-binding macrocycles using deep learning', Nature Chemical Biology. https://doi.org/10.1038/s41589-025-01929-w

TY - JOUR

T1 - Accurate de novo design of high-affinity protein-binding macrocycles using deep learning

AU - Rettie, Stephen A.

AU - Juergens, David

AU - Adebomi, Victor

AU - Bueso, Yensi Flores

AU - Zhao, Qinqin

AU - Leveille, Alexandria N.

AU - Liu, Andi

AU - Bera, Asim K.

AU - Wilms, Joana A.

AU - Üffing, Alina

AU - Kang, Alex

AU - Brackenbrough, Evans

AU - Lamb, Mila

AU - Gerben, Stacey R.

AU - Murray, Analisa

AU - Levine, Paul M.

AU - Schneider, Maika

AU - Vasireddy, Vibha

AU - Ovchinnikov, Sergey

AU - Weiergräber, Oliver H.

AU - Willbold, Dieter

AU - Kritzer, Joshua A.

AU - Mougous, Joseph D.

AU - Baker, David

AU - DiMaio, Frank

AU - Bhardwaj, Gaurav

PY - 2025

Y1 - 2025

N2 - Developing macrocyclic binders to therapeutic proteins typically relies on large-scale screening methods that are resource intensive and provide little control over binding mode. Despite progress in protein design, there are currently no robust approaches for de novo design of protein-binding macrocycles. Here we introduce RFpeptides, a denoising diffusion-based pipeline for designing macrocyclic binders against protein targets of interest. We tested 20 or fewer designed macrocycles against each of four diverse proteins and obtained binders with medium to high affinity against all targets. For one of the targets, Rhombotarget A (RbtA), we designed a high-affinity binder (Kd < 10 nM) despite starting from the predicted target structure. X-ray structures for macrocycle-bound myeloid cell leukemia 1, γ-aminobutyric acid type A receptor-associated protein and RbtA complexes match closely with the computational models, with a Cα root-mean-square deviation < 1.5 Å to the design models. RFpeptides provides a framework for rapid and custom design of macrocyclic peptides for diagnostic and therapeutic applications. (Figure presented.)

AB - Developing macrocyclic binders to therapeutic proteins typically relies on large-scale screening methods that are resource intensive and provide little control over binding mode. Despite progress in protein design, there are currently no robust approaches for de novo design of protein-binding macrocycles. Here we introduce RFpeptides, a denoising diffusion-based pipeline for designing macrocyclic binders against protein targets of interest. We tested 20 or fewer designed macrocycles against each of four diverse proteins and obtained binders with medium to high affinity against all targets. For one of the targets, Rhombotarget A (RbtA), we designed a high-affinity binder (Kd < 10 nM) despite starting from the predicted target structure. X-ray structures for macrocycle-bound myeloid cell leukemia 1, γ-aminobutyric acid type A receptor-associated protein and RbtA complexes match closely with the computational models, with a Cα root-mean-square deviation < 1.5 Å to the design models. RFpeptides provides a framework for rapid and custom design of macrocyclic peptides for diagnostic and therapeutic applications. (Figure presented.)

UR - https://www.scopus.com/pages/publications/105008455078

U2 - 10.1038/s41589-025-01929-w

DO - 10.1038/s41589-025-01929-w

M3 - Article

AN - SCOPUS:105008455078

SN - 1552-4450

JO - Nature Chemical Biology

JF - Nature Chemical Biology

ER -

Accurate de novo design of high-affinity protein-binding macrocycles using deep learning

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