Artificial intelligence for natural product drug discovery

Michael W. Mullowney, Katherine R. Duncan, Somayah S. Elsayed, Neha Garg, Justin J.J. van der Hooft, Nathaniel I. Martin, David Meijer, Barbara R. Terlouw, Friederike Biermann, Kai Blin, Janani Durairaj, Marina Gorostiola González, Eric J.N. Helfrich, Florian Huber, Stefan Leopold-Messer, Kohulan Rajan, Tristan de Rond, Jeffrey A. van Santen, Maria Sorokina, Marcy J. BalunasMehdi A. Beniddir, Doris A. van Bergeijk, Laura M. Carroll, Chase M. Clark, Djork Arné Clevert, Chris A. Dejong, Chao Du, Scarlet Ferrinho, Francesca Grisoni, Albert Hofstetter, Willem Jespers, Olga V. Kalinina, Satria A. Kautsar, Hyunwoo Kim, Tiago F. Leao, Joleen Masschelein, Evan R. Rees, Raphael Reher, Daniel Reker, Philippe Schwaller, Marwin Segler, Michael A. Skinnider, Allison S. Walker, Egon L. Willighagen, Barbara Zdrazil, Nadine Ziemert, Rebecca J.M. Goss, Pierre Guyomard, Andrea Volkamer, William H. Gerwick, Hyun Uk Kim, Rolf Müller, Gilles P. van Wezel, Gerard J.P. van Westen (Corresponding author), Anna K.H. Hirsch (Corresponding author), Roger G. Linington (Corresponding author), Serina L. Robinson (Corresponding author), Marnix H. Medema (Corresponding author)

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55 Citaten (Scopus)
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Samenvatting

Developments in computational omics technologies have provided new means to access the hidden diversity of natural products, unearthing new potential for drug discovery. In parallel, artificial intelligence approaches such as machine learning have led to exciting developments in the computational drug design field, facilitating biological activity prediction and de novo drug design for molecular targets of interest. Here, we describe current and future synergies between these developments to effectively identify drug candidates from the plethora of molecules produced by nature. We also discuss how to address key challenges in realizing the potential of these synergies, such as the need for high-quality datasets to train deep learning algorithms and appropriate strategies for algorithm validation.

Originele taal-2Engels
Pagina's (van-tot)895-916
Aantal pagina's22
TijdschriftNature Reviews. Drug Discovery
Volume22
Nummer van het tijdschrift11
DOI's
StatusGepubliceerd - nov. 2023

Bibliografische nota

Funding Information:
All authors thank the Lorentz Center and Leiden University for funding the Lorentz Workshop ‘Artificial Intelligence for Natural Product Drug Discovery’ that laid the foundation for this Review. M.W.M. was supported by funds from the Duchossois Family Institute at the University of Chicago. K.R.D. was supported by the UK Research and Innovation Biotechnology and Biological Sciences Research Council (BB/R022054/1). N.G. was supported by an NSF CAREER award (award number 2047235). J.J.J.v.d.H. was supported by an ASDI eScience grant from the Netherlands eScience Center (award number ASDI.2017.030). N.I.M. is supported by funding from the European Research Council (ERC consolidator grant agreement no. 725523). K.B. was supported by a Novo Nordisk Foundation grant NNF20CC0035580. M.G.G. was supported by ONCODE funding. E.J.N.H. was supported by the LOEWE Center for Translational Biodiversity Genomics and the Funds of the Chemical Industry Germany. M.S. was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project-ID 239748522, SFB 1127 ChemBioSys. M.A.B. was supported by the National French Agency (ANR grants 15-CE29-0001 and 20-CE43-0010). C.M.C. was supported by a National Library of Medicine training grant to the Computation and Informatics in Biology and Medicine Training Program (NLM 5T15LM007359). S.F. was supported by MASTS/IbioIC/Xanthella. O.V.K. was funded by the Klaus Faber Foundation. H.K. was supported by a National Research Foundation of Korea (NRF) grant funded by the Korean government (MSIT) (grants NRF 2018R1A5A2023127 and NRF 2022R1F1A107462311). J.M. was supported by a grant from the Research Foundation – Flanders (G061821N). E.R.R. was supported by the US National Science Foundation (DBI-1845890). D.R. was supported, in part, by a Flash Grant from NC Biotech (2021-FLG-3819), a UNC CGIBD Pilot Award (NIH NIDDK DK034987), a Duke Cancer Institute and Duke Microbiome Center Pilot Award (NIH NCI CA014236), the Engineering Research Center for Precision Microbiome Engineering (NSF EEC-2133504), and the Duke Science and Technology Initiative. P.S. acknowledges support from the NCCR Catalysis (grant number 180544), a National Centre of Competence in Research funded by the Swiss National Science Foundation. N.Z. was supported by Germany’s Excellence Strategy – EXC 2124-390838134. H.U.K. was supported by the KAIST Key Research Institute (Interdisciplinary Research Group) Project. R.G.L. was supported by the US NIH (U41-AT008718 and U24-AT010811). S.L.R. was supported by Eawag discretionary funding. M.H.M. was supported by the Leiden University ‘van der Klaauw’ chair for theoretical biology and an ERC Starting Grant (DECIPHER-948770). We thank A. R. Leach for discussion of the content of this manuscript. We thank all participants of the Lorentz Workshop ‘Artificial Intelligence for Natural Product Drug Discovery’ who did not participate in the review writing for providing inspiration through their talks and/or discussions.

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