plantiSMASH 2.0: Improvements to Detection, Annotation, and Prioritization of Plant Biosynthetic Gene Clusters

Elena Del Pup; Charlotte Owen; Ziqiang Luo; Hannah E. Augustijn; Arjan Draisma; Guy Polturak; Satria A. Kautsar; Anne Osbourn; Justin J.J. van der Hooft; Marnix H. Medema

doi:10.1016/j.jmb.2026.169798

plantiSMASH 2.0: Improvements to Detection, Annotation, and Prioritization of Plant Biosynthetic Gene Clusters

Elena Del Pup^*
, Charlotte Owen
, Ziqiang Luo
, Hannah E. Augustijn
, Arjan Draisma
, Guy Polturak
, Satria A. Kautsar
, Anne Osbourn^*
, Justin J.J. van der Hooft^*
, Marnix H. Medema^*

^*Corresponding author for this work

Institute of Plant Sciences and Genetics in Agriculture

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

Abstract

Plants produce bioactive compounds as part of their specialized metabolism, with applications in medicine, agriculture, and nutrition. The biosynthesis of a growing number of these specialized metabolites has been found to be encoded in biosynthetic gene clusters (BGCs), creating increasing demand for genome mining tools to automate their detection. plantiSMASH enables the identification of putative plant BGCs through a rule-based approach, available via both command-line and web interfaces. Here, we present plantiSMASH 2.0 (https://plantismash.bioinformatics.nl/), a major update that expands and improves the original framework with revised and additional BGC detection rules (now supporting 12 BGC types), substrate prediction for selected enzyme families, and regulatory analysis through transcription factor binding site detection. The updated plantiSMASH 2.0 database includes 30,423 putative BGCs across 430 genomes. Together, these improvements make plantiSMASH 2.0 a powerful and comprehensive platform for the detection and characterization of plant biosynthetic pathways, supporting and accelerating research in plant specialized metabolism and plant natural product discovery.

Original language	English
Article number	169798
Journal	Journal of Molecular Biology
DOIs	https://doi.org/10.1016/j.jmb.2026.169798
State	Accepted/In press - 2026

Bibliographical note

Publisher Copyright:
© 2026 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license. http://creativecommons.org/licenses/by/4.0/

Keywords

biosynthetic gene cluster
genome mining
natural product discovery
plant specialized metabolism
transcriptional regulation

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10.1016/j.jmb.2026.169798

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title = "plantiSMASH 2.0: Improvements to Detection, Annotation, and Prioritization of Plant Biosynthetic Gene Clusters",

abstract = "Plants produce bioactive compounds as part of their specialized metabolism, with applications in medicine, agriculture, and nutrition. The biosynthesis of a growing number of these specialized metabolites has been found to be encoded in biosynthetic gene clusters (BGCs), creating increasing demand for genome mining tools to automate their detection. plantiSMASH enables the identification of putative plant BGCs through a rule-based approach, available via both command-line and web interfaces. Here, we present plantiSMASH 2.0 (https://plantismash.bioinformatics.nl/), a major update that expands and improves the original framework with revised and additional BGC detection rules (now supporting 12 BGC types), substrate prediction for selected enzyme families, and regulatory analysis through transcription factor binding site detection. The updated plantiSMASH 2.0 database includes 30,423 putative BGCs across 430 genomes. Together, these improvements make plantiSMASH 2.0 a powerful and comprehensive platform for the detection and characterization of plant biosynthetic pathways, supporting and accelerating research in plant specialized metabolism and plant natural product discovery.",

keywords = "biosynthetic gene cluster, genome mining, natural product discovery, plant specialized metabolism, transcriptional regulation",

author = "\{Del Pup\}, Elena and Charlotte Owen and Ziqiang Luo and Augustijn, \{Hannah E.\} and Arjan Draisma and Guy Polturak and Kautsar, \{Satria A.\} and Anne Osbourn and \{van der Hooft\}, \{Justin J.J.\} and Medema, \{Marnix H.\}",

note = "Publisher Copyright: {\textcopyright} 2026 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license. http://creativecommons.org/licenses/by/4.0/",

year = "2026",

doi = "10.1016/j.jmb.2026.169798",

language = "אנגלית",

journal = "Journal of Molecular Biology",

issn = "0022-2836",

publisher = "Academic Press",

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T2 - Improvements to Detection, Annotation, and Prioritization of Plant Biosynthetic Gene Clusters

AU - Del Pup, Elena

AU - Owen, Charlotte

AU - Luo, Ziqiang

AU - Augustijn, Hannah E.

AU - Draisma, Arjan

AU - Polturak, Guy

AU - Kautsar, Satria A.

AU - Osbourn, Anne

AU - van der Hooft, Justin J.J.

AU - Medema, Marnix H.

PY - 2026

Y1 - 2026

N2 - Plants produce bioactive compounds as part of their specialized metabolism, with applications in medicine, agriculture, and nutrition. The biosynthesis of a growing number of these specialized metabolites has been found to be encoded in biosynthetic gene clusters (BGCs), creating increasing demand for genome mining tools to automate their detection. plantiSMASH enables the identification of putative plant BGCs through a rule-based approach, available via both command-line and web interfaces. Here, we present plantiSMASH 2.0 (https://plantismash.bioinformatics.nl/), a major update that expands and improves the original framework with revised and additional BGC detection rules (now supporting 12 BGC types), substrate prediction for selected enzyme families, and regulatory analysis through transcription factor binding site detection. The updated plantiSMASH 2.0 database includes 30,423 putative BGCs across 430 genomes. Together, these improvements make plantiSMASH 2.0 a powerful and comprehensive platform for the detection and characterization of plant biosynthetic pathways, supporting and accelerating research in plant specialized metabolism and plant natural product discovery.

AB - Plants produce bioactive compounds as part of their specialized metabolism, with applications in medicine, agriculture, and nutrition. The biosynthesis of a growing number of these specialized metabolites has been found to be encoded in biosynthetic gene clusters (BGCs), creating increasing demand for genome mining tools to automate their detection. plantiSMASH enables the identification of putative plant BGCs through a rule-based approach, available via both command-line and web interfaces. Here, we present plantiSMASH 2.0 (https://plantismash.bioinformatics.nl/), a major update that expands and improves the original framework with revised and additional BGC detection rules (now supporting 12 BGC types), substrate prediction for selected enzyme families, and regulatory analysis through transcription factor binding site detection. The updated plantiSMASH 2.0 database includes 30,423 putative BGCs across 430 genomes. Together, these improvements make plantiSMASH 2.0 a powerful and comprehensive platform for the detection and characterization of plant biosynthetic pathways, supporting and accelerating research in plant specialized metabolism and plant natural product discovery.

KW - biosynthetic gene cluster

KW - genome mining

KW - natural product discovery

KW - plant specialized metabolism

KW - transcriptional regulation

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ER -

plantiSMASH 2.0: Improvements to Detection, Annotation, and Prioritization of Plant Biosynthetic Gene Clusters

Abstract

Bibliographical note

Keywords

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