CACHE Challenge #3: Targeting the Nsp3 Macrodomain of SARS-CoV-2

Oleksandra Herasymenko; Madhushika Silva; Galen J. Correy; Abd Al Aziz A. Abu-Saleh; Suzanne Ackloo; Cheryl Arrowsmith; Alan Ashworth; Fuqiang Ban; Hartmut Beck; Kevin P. Bishop; Hugo J. Bohórquez; Albina Bolotokova; Marko Breznik; Irene Chau; Yu Chen; Artem Cherkasov; Wim Dehaen; Dennis Della Corte; Katrin Denzinger; Niklas P. Doering; Kristina Edfeldt; Aled Edwards; Darren Fayne; Francesco Gentile; Elisa Gibson; Ozan Gokdemir; Anders Gunnarsson; Judith Günther; John J. Irwin; Jan Halborg Jensen; Rachel J. Harding; Alexander Hillisch; Laurent Hoffer; Anders Hogner; Ashley Hutchinson; Shubhangi Kandwal; Andrea Karlova; Kushal Koirala; Sergei Kotelnikov; Dima Kozakov; Juyong Lee; Soowon Lee; Uta Lessel; Sijie Liu; Xuefeng Liu; Peter Loppnau; Jens Meiler; Rocco Moretti; Yurii S. Moroz; Charuvaka Muvva; Tudor I. Oprea; Brooks Paige; Amit Pandit; Keunwan Park; Gennady Poda; Mykola V. Protopopov; Vera Pütter; Rahul Ravichandran; Didier Rognan; Edina Rosta; Yogesh Sabnis; Thomas Scott; Almagul Seitova; Purshotam Sharma; François Sindt; Minghu Song; Casper Steinmann; Rick Stevens; Valerij Talagayev; Valentyna V. Tararina; Olga Tarkhanova; Damon Tingey; John F. Trant; Dakota Treleaven; Alexander Tropsha; Patrick Walters; Jude Wells; Yvonne Westermaier; Gerhard Wolber; Lars Wortmann; Shuangjia Zheng; James S. Fraser; Matthieu Schapira

doi:10.1021/acs.jcim.5c02441

CACHE Challenge #3: Targeting the Nsp3 Macrodomain of SARS-CoV-2

Oleksandra Herasymenko
, Madhushika Silva
, Galen J. Correy
, Abd Al Aziz A. Abu-Saleh
, Suzanne Ackloo
, Cheryl Arrowsmith
, Alan Ashworth
, Fuqiang Ban
, Hartmut Beck
, Kevin P. Bishop
, Hugo J. Bohórquez
, Albina Bolotokova
, Marko Breznik
, Irene Chau
, Yu Chen
, Artem Cherkasov
, Wim Dehaen
, Dennis Della Corte
, Katrin Denzinger
, Niklas P. Doering

Kristina Edfeldt, Aled Edwards, Darren Fayne, Francesco Gentile, Elisa Gibson, Ozan Gokdemir, Anders Gunnarsson, Judith Günther, John J. Irwin, Jan Halborg Jensen, Rachel J. Harding, Alexander Hillisch, Laurent Hoffer, Anders Hogner, Ashley Hutchinson, Shubhangi Kandwal, Andrea Karlova, Kushal Koirala, Sergei Kotelnikov, Dima Kozakov, Juyong Lee, Soowon Lee, Uta Lessel, Sijie Liu, Xuefeng Liu, Peter Loppnau, Jens Meiler, Rocco Moretti, Yurii S. Moroz, Charuvaka Muvva, Tudor I. Oprea, Brooks Paige, Amit Pandit, Keunwan Park, Gennady Poda, Mykola V. Protopopov, Vera Pütter, Rahul Ravichandran, Didier Rognan, Edina Rosta, Yogesh Sabnis, Thomas Scott, Almagul Seitova, Purshotam Sharma, François Sindt, Minghu Song, Casper Steinmann, Rick Stevens, Valerij Talagayev, Valentyna V. Tararina, Olga Tarkhanova, Damon Tingey, John F. Trant, Dakota Treleaven, Alexander Tropsha, Patrick Walters, Jude Wells, Yvonne Westermaier, Gerhard Wolber, Lars Wortmann, Shuangjia Zheng, James S. Fraser, Matthieu Schapira

Applied Mathematics and Statistics

Centre of Excellence on Aging and Chronic Diseases of McGill Integrated University Health Network
University of California at San Francisco
University of Windsor
Binary Star Research Services
University of Toronto
Princess Margaret Cancer Centre
Vancouver Prostate Centre
Bayer AG
Ontario Institute for Cancer Research
QuAccel
Free University of Berlin
University of British Columbia
University of Chemistry and Technology, Prague
Brigham Young University
Karolinska Institutet
Dublin City University
University of Ottawa
The University of Chicago
Argonne National Laboratory
AstraZeneca
University of Copenhagen
UCB S.A.
Trinity College Dublin
University College London
University of North Carolina at Chapel Hill
Stony Brook University
Seoul National University
Arontier Co.
Boehringer Ingelheim GmbH
Leipzig University
Center for Scalable Data Analytics and Artificial Intelligence ScaDS.AI Dresden/Leipzig and School of Embedded Composite Artificial Intelligence SECAI
Vanderbilt University
Chemspace LLC
Korea Institute of Science and Technology
Experts System Inc.
SVKM's NMIMS
Nuvisan ICB GmbH
UMR7200 CNRS-Université de Strasbourg
Hefei Comprehensive National Science Center
Aalborg University
Kyiv National Taras Shevchenko University
Conscience Medicines Network
Relay Therapeutics
Shanghai Jiao Tong University

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

1 Scopus citations

Abstract

The third Critical Assessment of Computational Hit-finding Experiments (CACHE) challenged computational teams to identify chemically novel ligands targeting the macrodomain 1 of SARS-CoV-2 Nsp3, a promising coronavirus drug target. Twenty-three groups deployed diverse design strategies to collectively select 1739 ligand candidates. While over 85% of the designed molecules were chemically novel, the best experimentally confirmed hits were structurally similar to previously published compounds. Confirming a trend observed in CACHE #1 and #2, two of the best-performing workflows used compounds selected by physics-based computational screening methods to train machine learning models able to rapidly screen large chemical libraries, while four others used exclusively physics-based approaches. Three pharmacophore searches and one fragment growing strategy were also part of the seven winning workflows. While active molecules discovered by CACHE #3 participants largely mimicked the adenine ring of the endogenous substrate, ADP-ribose, preserving the canonical chemotype commonly observed in previously reported Nsp3-Mac1 ligands, they still provide novel structure–activity relationship insights that may inform the development of future antivirals. Collectively, these results show that multiple molecular design strategies can efficiently converge on similar potent molecules.

Original language	English
Pages (from-to)	1566-1581
Number of pages	16
Journal	Journal of Chemical Information and Modeling
Volume	66
Issue number	3
DOIs	https://doi.org/10.1021/acs.jcim.5c02441
State	Published - Feb 9 2026

Access to Document

10.1021/acs.jcim.5c02441

Cite this

Herasymenko, O., Silva, M., Correy, G. J., Abu-Saleh, A. A. A. A., Ackloo, S., Arrowsmith, C., Ashworth, A., Ban, F., Beck, H., Bishop, K. P., Bohórquez, H. J., Bolotokova, A., Breznik, M., Chau, I., Chen, Y., Cherkasov, A., Dehaen, W., Della Corte, D., Denzinger, K., ... Schapira, M. (2026). CACHE Challenge #3: Targeting the Nsp3 Macrodomain of SARS-CoV-2. Journal of Chemical Information and Modeling, 66(3), 1566-1581. https://doi.org/10.1021/acs.jcim.5c02441

@article{54f88dea09194057a7fdda6cc3b9753b,

title = "CACHE Challenge \#3: Targeting the Nsp3 Macrodomain of SARS-CoV-2",

abstract = "The third Critical Assessment of Computational Hit-finding Experiments (CACHE) challenged computational teams to identify chemically novel ligands targeting the macrodomain 1 of SARS-CoV-2 Nsp3, a promising coronavirus drug target. Twenty-three groups deployed diverse design strategies to collectively select 1739 ligand candidates. While over 85\% of the designed molecules were chemically novel, the best experimentally confirmed hits were structurally similar to previously published compounds. Confirming a trend observed in CACHE \#1 and \#2, two of the best-performing workflows used compounds selected by physics-based computational screening methods to train machine learning models able to rapidly screen large chemical libraries, while four others used exclusively physics-based approaches. Three pharmacophore searches and one fragment growing strategy were also part of the seven winning workflows. While active molecules discovered by CACHE \#3 participants largely mimicked the adenine ring of the endogenous substrate, ADP-ribose, preserving the canonical chemotype commonly observed in previously reported Nsp3-Mac1 ligands, they still provide novel structure–activity relationship insights that may inform the development of future antivirals. Collectively, these results show that multiple molecular design strategies can efficiently converge on similar potent molecules.",

author = "Oleksandra Herasymenko and Madhushika Silva and Correy, \{Galen J.\} and Abu-Saleh, \{Abd Al Aziz A.\} and Suzanne Ackloo and Cheryl Arrowsmith and Alan Ashworth and Fuqiang Ban and Hartmut Beck and Bishop, \{Kevin P.\} and Boh{\'o}rquez, \{Hugo J.\} and Albina Bolotokova and Marko Breznik and Irene Chau and Yu Chen and Artem Cherkasov and Wim Dehaen and \{Della Corte\}, Dennis and Katrin Denzinger and Doering, \{Niklas P.\} and Kristina Edfeldt and Aled Edwards and Darren Fayne and Francesco Gentile and Elisa Gibson and Ozan Gokdemir and Anders Gunnarsson and Judith G{\"u}nther and Irwin, \{John J.\} and Jensen, \{Jan Halborg\} and Harding, \{Rachel J.\} and Alexander Hillisch and Laurent Hoffer and Anders Hogner and Ashley Hutchinson and Shubhangi Kandwal and Andrea Karlova and Kushal Koirala and Sergei Kotelnikov and Dima Kozakov and Juyong Lee and Soowon Lee and Uta Lessel and Sijie Liu and Xuefeng Liu and Peter Loppnau and Jens Meiler and Rocco Moretti and Moroz, \{Yurii S.\} and Charuvaka Muvva and Oprea, \{Tudor I.\} and Brooks Paige and Amit Pandit and Keunwan Park and Gennady Poda and Protopopov, \{Mykola V.\} and Vera P{\"u}tter and Rahul Ravichandran and Didier Rognan and Edina Rosta and Yogesh Sabnis and Thomas Scott and Almagul Seitova and Purshotam Sharma and Fran{\c c}ois Sindt and Minghu Song and Casper Steinmann and Rick Stevens and Valerij Talagayev and Tararina, \{Valentyna V.\} and Olga Tarkhanova and Damon Tingey and Trant, \{John F.\} and Dakota Treleaven and Alexander Tropsha and Patrick Walters and Jude Wells and Yvonne Westermaier and Gerhard Wolber and Lars Wortmann and Shuangjia Zheng and Fraser, \{James S.\} and Matthieu Schapira",

note = "Publisher Copyright: {\textcopyright} 2026 The Authors. Published by American Chemical Society",

year = "2026",

month = feb,

day = "9",

doi = "10.1021/acs.jcim.5c02441",

language = "English",

volume = "66",

pages = "1566--1581",

journal = "Journal of Chemical Information and Modeling",

issn = "1549-9596",

number = "3",

}

Herasymenko, O, Silva, M, Correy, GJ, Abu-Saleh, AAAA, Ackloo, S, Arrowsmith, C, Ashworth, A, Ban, F, Beck, H, Bishop, KP, Bohórquez, HJ, Bolotokova, A, Breznik, M, Chau, I, Chen, Y, Cherkasov, A, Dehaen, W, Della Corte, D, Denzinger, K, Doering, NP, Edfeldt, K, Edwards, A, Fayne, D, Gentile, F, Gibson, E, Gokdemir, O, Gunnarsson, A, Günther, J, Irwin, JJ, Jensen, JH, Harding, RJ, Hillisch, A, Hoffer, L, Hogner, A, Hutchinson, A, Kandwal, S, Karlova, A, Koirala, K, Kotelnikov, S, Kozakov, D, Lee, J, Lee, S, Lessel, U, Liu, S, Liu, X, Loppnau, P, Meiler, J, Moretti, R, Moroz, YS, Muvva, C, Oprea, TI, Paige, B, Pandit, A, Park, K, Poda, G, Protopopov, MV, Pütter, V, Ravichandran, R, Rognan, D, Rosta, E, Sabnis, Y, Scott, T, Seitova, A, Sharma, P, Sindt, F, Song, M, Steinmann, C, Stevens, R, Talagayev, V, Tararina, VV, Tarkhanova, O, Tingey, D, Trant, JF, Treleaven, D, Tropsha, A, Walters, P, Wells, J, Westermaier, Y, Wolber, G, Wortmann, L, Zheng, S, Fraser, JS & Schapira, M 2026, 'CACHE Challenge #3: Targeting the Nsp3 Macrodomain of SARS-CoV-2', Journal of Chemical Information and Modeling, vol. 66, no. 3, pp. 1566-1581. https://doi.org/10.1021/acs.jcim.5c02441

TY - JOUR

T1 - CACHE Challenge #3

T2 - Targeting the Nsp3 Macrodomain of SARS-CoV-2

AU - Herasymenko, Oleksandra

AU - Silva, Madhushika

AU - Correy, Galen J.

AU - Abu-Saleh, Abd Al Aziz A.

AU - Ackloo, Suzanne

AU - Arrowsmith, Cheryl

AU - Ashworth, Alan

AU - Ban, Fuqiang

AU - Beck, Hartmut

AU - Bishop, Kevin P.

AU - Bohórquez, Hugo J.

AU - Bolotokova, Albina

AU - Breznik, Marko

AU - Chau, Irene

AU - Chen, Yu

AU - Cherkasov, Artem

AU - Dehaen, Wim

AU - Della Corte, Dennis

AU - Denzinger, Katrin

AU - Doering, Niklas P.

AU - Edfeldt, Kristina

AU - Edwards, Aled

AU - Fayne, Darren

AU - Gentile, Francesco

AU - Gibson, Elisa

AU - Gokdemir, Ozan

AU - Gunnarsson, Anders

AU - Günther, Judith

AU - Irwin, John J.

AU - Jensen, Jan Halborg

AU - Harding, Rachel J.

AU - Hillisch, Alexander

AU - Hoffer, Laurent

AU - Hogner, Anders

AU - Hutchinson, Ashley

AU - Kandwal, Shubhangi

AU - Karlova, Andrea

AU - Koirala, Kushal

AU - Kotelnikov, Sergei

AU - Kozakov, Dima

AU - Lee, Juyong

AU - Lee, Soowon

AU - Lessel, Uta

AU - Liu, Sijie

AU - Liu, Xuefeng

AU - Loppnau, Peter

AU - Meiler, Jens

AU - Moretti, Rocco

AU - Moroz, Yurii S.

AU - Muvva, Charuvaka

AU - Oprea, Tudor I.

AU - Paige, Brooks

AU - Pandit, Amit

AU - Park, Keunwan

AU - Poda, Gennady

AU - Protopopov, Mykola V.

AU - Pütter, Vera

AU - Ravichandran, Rahul

AU - Rognan, Didier

AU - Rosta, Edina

AU - Sabnis, Yogesh

AU - Scott, Thomas

AU - Seitova, Almagul

AU - Sharma, Purshotam

AU - Sindt, François

AU - Song, Minghu

AU - Steinmann, Casper

AU - Stevens, Rick

AU - Talagayev, Valerij

AU - Tararina, Valentyna V.

AU - Tarkhanova, Olga

AU - Tingey, Damon

AU - Trant, John F.

AU - Treleaven, Dakota

AU - Tropsha, Alexander

AU - Walters, Patrick

AU - Wells, Jude

AU - Westermaier, Yvonne

AU - Wolber, Gerhard

AU - Wortmann, Lars

AU - Zheng, Shuangjia

AU - Fraser, James S.

AU - Schapira, Matthieu

PY - 2026/2/9

Y1 - 2026/2/9

N2 - The third Critical Assessment of Computational Hit-finding Experiments (CACHE) challenged computational teams to identify chemically novel ligands targeting the macrodomain 1 of SARS-CoV-2 Nsp3, a promising coronavirus drug target. Twenty-three groups deployed diverse design strategies to collectively select 1739 ligand candidates. While over 85% of the designed molecules were chemically novel, the best experimentally confirmed hits were structurally similar to previously published compounds. Confirming a trend observed in CACHE #1 and #2, two of the best-performing workflows used compounds selected by physics-based computational screening methods to train machine learning models able to rapidly screen large chemical libraries, while four others used exclusively physics-based approaches. Three pharmacophore searches and one fragment growing strategy were also part of the seven winning workflows. While active molecules discovered by CACHE #3 participants largely mimicked the adenine ring of the endogenous substrate, ADP-ribose, preserving the canonical chemotype commonly observed in previously reported Nsp3-Mac1 ligands, they still provide novel structure–activity relationship insights that may inform the development of future antivirals. Collectively, these results show that multiple molecular design strategies can efficiently converge on similar potent molecules.

AB - The third Critical Assessment of Computational Hit-finding Experiments (CACHE) challenged computational teams to identify chemically novel ligands targeting the macrodomain 1 of SARS-CoV-2 Nsp3, a promising coronavirus drug target. Twenty-three groups deployed diverse design strategies to collectively select 1739 ligand candidates. While over 85% of the designed molecules were chemically novel, the best experimentally confirmed hits were structurally similar to previously published compounds. Confirming a trend observed in CACHE #1 and #2, two of the best-performing workflows used compounds selected by physics-based computational screening methods to train machine learning models able to rapidly screen large chemical libraries, while four others used exclusively physics-based approaches. Three pharmacophore searches and one fragment growing strategy were also part of the seven winning workflows. While active molecules discovered by CACHE #3 participants largely mimicked the adenine ring of the endogenous substrate, ADP-ribose, preserving the canonical chemotype commonly observed in previously reported Nsp3-Mac1 ligands, they still provide novel structure–activity relationship insights that may inform the development of future antivirals. Collectively, these results show that multiple molecular design strategies can efficiently converge on similar potent molecules.

UR - https://www.scopus.com/pages/publications/105029663938

U2 - 10.1021/acs.jcim.5c02441

DO - 10.1021/acs.jcim.5c02441

M3 - Article

C2 - 41565251

AN - SCOPUS:105029663938

SN - 1549-9596

VL - 66

SP - 1566

EP - 1581

JO - Journal of Chemical Information and Modeling

JF - Journal of Chemical Information and Modeling

IS - 3

ER -

CACHE Challenge #3: Targeting the Nsp3 Macrodomain of SARS-CoV-2

Abstract

Access to Document

Other files and links

Fingerprint

Cite this