Your search keyword '"Weber, Tilmann"' showing total 11 results

1. The antiSMASH database version 4: additional genomes and BGCs, new sequence-based searches and more

Author

Blin, Kai, Shaw, Simon, Medema, Marnix, Weber, Tilmann, Blin, Kai, Shaw, Simon, Medema, Marnix, and Weber, Tilmann

Abstract

Many microorganisms produce natural products that are frequently used in the development of medicines and crop protection agents. Genome mining has evolved into a prominent method to access this potential. antiSMASH is the most popular tool for this task. Here we present version 4 of the antiSMASH database, providing biosynthetic gene clusters detected by antiSMASH 7.1 in publicly available, dereplicated, high-quality microbial genomes via an interactive graphical user interface. In version 4, the database contains 231 534 high quality BGC regions from 592 archaeal, 35 726 bacterial and 236 fungal genomes and is available at https://antismash-db.secondarymetabolites.org/.

Published

2024

2. AntiSMASH 7.0 : New and improved predictions for detection, regulation, chemical structures and visualisation

Author

Blin, Kai, Shaw, Simon, Augustijn, Hannah E., Reitz, Zachary L., Biermann, Friederike, Alanjary, Mohammad, Fetter, Artem, Terlouw, Barbara R., Metcalf, William W., Helfrich, Eric J.N., Van Wezel, Gilles P., Medema, Marnix H., Weber, Tilmann, Blin, Kai, Shaw, Simon, Augustijn, Hannah E., Reitz, Zachary L., Biermann, Friederike, Alanjary, Mohammad, Fetter, Artem, Terlouw, Barbara R., Metcalf, William W., Helfrich, Eric J.N., Van Wezel, Gilles P., Medema, Marnix H., and Weber, Tilmann

Abstract

Microorganisms produce small bioactive compounds as part of their secondary or specialised metabolism. Often, such metabolites have antimicrobial, anticancer, antifungal, antiviral or other bio-Activities and thus play an important role for applications in medicine and agriculture. In the past decade, genome mining has become a widely-used method to explore, access, and analyse the available biodiversity of these compounds. Since 2011, the 'antibiotics and secondary metabolite analysis shell-antiSMASH' (https://antismash.secondarymetabolites.org/) has supported researchers in their microbial genome mining tasks, both as a free to use web server and as a standalone tool under an OSI-Approved open source licence. It is currently the most widely used tool for detecting and characterising biosynthetic gene clusters (BGCs) in archaea, bacteria, and fungi. Here, we present the updated version 7 of antiSMASH. antiSMASH 7 increases the number of supported cluster types from 71 to 81, as well as containing improvements in the areas of chemical structure prediction, enzymatic assembly-line visualisation and gene cluster regulation.

Published

2023

3. MIBiG 3.0: a community-driven effort to annotate experimentally validated biosynthetic gene clusters

Author

Terlouw, Barbara R., Blin, Kai, Navarro-Muñoz, Jorge C., Avalon, Nicole E., Chevrette, Marc G., Egbert, Susan, Lee, Sanghoon, Meijer, David, Recchia, Michael J.J., Reitz, Zachary L., van Santen, Jeffrey A., Selem-Mojica, Nelly, Tørring, Thomas, Zaroubi, Liana, Alanjary, Mohammad, Aleti, Gajender, Aguilar, César, Al-Salihi, Suhad A.A., Augustijn, Hannah E., Avelar-Rivas, J.A., Avitia-Domínguez, Luis A., Barona-Gómez, Francisco, Bernaldo-Agüero, Jordan, Bielinski, Vincent A., Biermann, Friederike, Booth, Thomas J., Carrion Bravo, Victor J., Castelo-Branco, Raquel, Chagas, Fernanda O., Cruz-Morales, Pablo, Du, Chao, Duncan, Katherine R., Gavriilidou, Athina, Gayrard, Damien, Gutiérrez-García, Karina, Haslinger, Kristina, Helfrich, Eric J.N., van der Hooft, Justin J.J., Jati, Afif P., Kalkreuter, Edward, Kalyvas, Nikolaos, Kang, Kyo Bin, Kautsar, Satria, Kim, Wonyong, Kunjapur, Aditya M., Li, Yong-Xin, Lin, Geng-Min, Loureiro, Catarina, Louwen, Joris J.R., Louwen, Nico L.L., Lund, George, Parra, Jonathan, Philmus, Benjamin, Pourmohsenin, Bita, Pronk, Lotte J.U., Rego, Adriana, Rex, Devasahayam Arokia Balaya, Robinson, Serina, Rosas-Becerra, L.R., Roxborough, Eve T., Schorn, Michelle A., Scobie, Darren J., Singh, Kumar Saurabh, Sokolova, Nika, Tang, Xiaoyu, Udwary, Daniel, Vigneshwari, Aruna, Vind, Kristiina, Vromans, Sophie P.J.M., Waschulin, Valentin, Williams, Sam E., Winter, Jaclyn M., Witte, Thomas E., Xie, Huali, Yang, Dong, Yu, Jingwei, Zdouc, Mitja, Zhong, Zheng, Collemare, Jérôme, Linington, Roger G., Weber, Tilmann, Medema, Marnix H., Terlouw, Barbara R., Blin, Kai, Navarro-Muñoz, Jorge C., Avalon, Nicole E., Chevrette, Marc G., Egbert, Susan, Lee, Sanghoon, Meijer, David, Recchia, Michael J.J., Reitz, Zachary L., van Santen, Jeffrey A., Selem-Mojica, Nelly, Tørring, Thomas, Zaroubi, Liana, Alanjary, Mohammad, Aleti, Gajender, Aguilar, César, Al-Salihi, Suhad A.A., Augustijn, Hannah E., Avelar-Rivas, J.A., Avitia-Domínguez, Luis A., Barona-Gómez, Francisco, Bernaldo-Agüero, Jordan, Bielinski, Vincent A., Biermann, Friederike, Booth, Thomas J., Carrion Bravo, Victor J., Castelo-Branco, Raquel, Chagas, Fernanda O., Cruz-Morales, Pablo, Du, Chao, Duncan, Katherine R., Gavriilidou, Athina, Gayrard, Damien, Gutiérrez-García, Karina, Haslinger, Kristina, Helfrich, Eric J.N., van der Hooft, Justin J.J., Jati, Afif P., Kalkreuter, Edward, Kalyvas, Nikolaos, Kang, Kyo Bin, Kautsar, Satria, Kim, Wonyong, Kunjapur, Aditya M., Li, Yong-Xin, Lin, Geng-Min, Loureiro, Catarina, Louwen, Joris J.R., Louwen, Nico L.L., Lund, George, Parra, Jonathan, Philmus, Benjamin, Pourmohsenin, Bita, Pronk, Lotte J.U., Rego, Adriana, Rex, Devasahayam Arokia Balaya, Robinson, Serina, Rosas-Becerra, L.R., Roxborough, Eve T., Schorn, Michelle A., Scobie, Darren J., Singh, Kumar Saurabh, Sokolova, Nika, Tang, Xiaoyu, Udwary, Daniel, Vigneshwari, Aruna, Vind, Kristiina, Vromans, Sophie P.J.M., Waschulin, Valentin, Williams, Sam E., Winter, Jaclyn M., Witte, Thomas E., Xie, Huali, Yang, Dong, Yu, Jingwei, Zdouc, Mitja, Zhong, Zheng, Collemare, Jérôme, Linington, Roger G., Weber, Tilmann, and Medema, Marnix H.

Abstract

With an ever-increasing amount of (meta)genomic data being deposited in sequence databases, (meta)genome mining for natural product biosynthetic pathways occupies a critical role in the discovery of novel pharmaceutical drugs, crop protection agents and biomaterials. The genes that encode these pathways are often organised into biosynthetic gene clusters (BGCs). In 2015, we defined the Minimum Information about a Biosynthetic Gene cluster (MIBiG): a standardised data format that describes the minimally required information to uniquely characterise a BGC. We simultaneously constructed an accompanying online database of BGCs, which has since been widely used by the community as a reference dataset for BGCs and was expanded to 2021 entries in 2019 (MIBiG 2.0). Here, we describe MIBiG 3.0, a database update comprising large-scale validation and re-annotation of existing entries and 661 new entries. Particular attention was paid to the annotation of compound structures and biological activities, as well as protein domain selectivities. Together, these new features keep the database up-to-date, and will provide new opportunities for the scientific community to use its freely available data, e.g. for the training of new machine learning models to predict sequence-structure-function relationships for diverse natural products.

Published

2023

4. The antiSMASH database version 3 : increased taxonomic coverage and new query features for modular enzymes

Author

Blin, Kai, Shaw, Simon, Kautsar, Satria A., Medema, Marnix H., Weber, Tilmann, Blin, Kai, Shaw, Simon, Kautsar, Satria A., Medema, Marnix H., and Weber, Tilmann

Abstract

Microorganisms produce natural products that are frequently used in the development of antibacterial, antiviral, and anticancer drugs, pesticides, herbicides, or fungicides. In recent years, genome mining has evolved into a prominent method to access this potential. antiSMASH is one of the most popular tools for this task. Here, we present version 3 of the antiSMASH database, providing a means to access and query precomputed antiSMASH-5.2-detected biosynthetic gene clusters from representative, publicly available, high-quality microbial genomes via an interactive graphical user interface. In version 3, the database contains 147 517 high quality BGC regions from 388 archaeal, 25 236 bacterial and 177 fungal genomes and is available at https://antismash-db.secondarymetabolites.org/.

Published

2021

5. BiG-FAM: the biosynthetic gene cluster families database

Author

Kautsar, Satria A., Blin, Kai, Shaw, Simon, Weber, Tilmann, Medema, Marnix H., Kautsar, Satria A., Blin, Kai, Shaw, Simon, Weber, Tilmann, and Medema, Marnix H.

Abstract

Computational analysis of biosynthetic gene clusters (BGCs) has revolutionized natural product discovery by enabling the rapid investigation of secondary metabolic potential within microbial genome sequences. Grouping homologous BGCs into Gene Cluster Families (GCFs) facilitates mapping their architectural and taxonomic diversity and provides insights into the novelty of putative BGCs, through dereplication with BGCs of known function. While multiple databases exist for exploring BGCs from publicly available data, no public resources exist that focus on GCF relationships. Here, we present BiG-FAM, a database of 29,955 GCFs capturing the global diversity of 1,225,071 BGCs predicted from 209,206 publicly available microbial genomes and metagenome-assembled genomes (MAGs). The database offers rich functionalities, such as multi-criterion GCF searches, direct links to BGC databases such as antiSMASH-DB, and rapid GCF annotation of user-supplied BGCs from antiSMASH results. BiG-FAM can be accessed online at https://bigfam.bioinformatics.nl.

Published

2021

6. AntiSMASH 6.0 : Improving cluster detection and comparison capabilities

Author

Blin, Kai, Shaw, Simon, Kloosterman, Alexander M., Charlop-Powers, Zach, Van Wezel, Gilles P., Medema, Marnix H., Weber, Tilmann, Blin, Kai, Shaw, Simon, Kloosterman, Alexander M., Charlop-Powers, Zach, Van Wezel, Gilles P., Medema, Marnix H., and Weber, Tilmann

Abstract

Many microorganisms produce natural products that form the basis of antimicrobials, antivirals, and other drugs. Genome mining is routinely used to complement screening-based workflows to discover novel natural products. Since 2011, the "antibiotics and secondary metabolite analysis shell - antiSMASH"(https://antismash.secondarymetabolites.org/) has supported researchers in their microbial genome mining tasks, both as a free-to-use web server and as a standalone tool under an OSI-approved open-source license. It is currently the most widely used tool for detecting and characterising biosynthetic gene clusters (BGCs) in bacteria and fungi. Here, we present the updated version 6 of antiSMASH. antiSMASH 6 increases the number of supported cluster types from 58 to 71, displays the modular structure of multi-modular BGCs, adds a new BGC comparison algorithm, allows for the integration of results from other prediction tools, and more effectively detects tailoring enzymes in RiPP clusters.

Published

2021

7. MIBiG 2.0: a repository for biosynthetic gene clusters of known functions

Author

Kautsar, S.A., Blin, Kai, Shaw, Simon, Navarro Munoz, J.C., Terlouw, Barbara, van der Hooft, J.J.J., Van Santen, Jeffrey A., Tracanna, V., Suarez Duran, Hernando, Pascal Andreu, V., Selem Mojica, Nelly, Alanjary, Mohammad, Robinson, Serina, Lund, George, Epstein, Samuel C., Sisto, Ashley C., Charkoudian, Louise K., Collemare, Jérôme, Linington, Roger G., Weber, Tilmann, Medema, M.H., Kautsar, S.A., Blin, Kai, Shaw, Simon, Navarro Munoz, J.C., Terlouw, Barbara, van der Hooft, J.J.J., Van Santen, Jeffrey A., Tracanna, V., Suarez Duran, Hernando, Pascal Andreu, V., Selem Mojica, Nelly, Alanjary, Mohammad, Robinson, Serina, Lund, George, Epstein, Samuel C., Sisto, Ashley C., Charkoudian, Louise K., Collemare, Jérôme, Linington, Roger G., Weber, Tilmann, and Medema, M.H.

Abstract

Fueled by the explosion of (meta)genomic data, genome mining of specialized metabolites has become a major technology for drug discovery and studying microbiome ecology. In these efforts, computational tools like antiSMASH have played a central role through the analysis of Biosynthetic Gene Clusters (BGCs). Thousands of candidate BGCs from microbial genomes have been identified and stored in public databases. Interpreting the function and novelty of these predicted BGCs requires comparison with a well-documented set of BGCs of known function. The MIBiG (Minimum Information about a Biosynthetic Gene Cluster) Data Standard and Repository was established in 2015 to enable curation and storage of known BGCs. Here, we present MIBiG 2.0, which encompasses major updates to the schema, the data, and the online repository itself. Over the past five years, 851 new BGCs have been added. Additionally, we performed extensive manual data curation of all entries to improve the annotation quality of our repository. We also redesigned the data schema to ensure the compliance of future annotations. Finally, we improved the user experience by adding new features such as query searches and a statistics page, and enabled direct link-outs to chemical structure databases. The repository is accessible online at https://mibig.secondarymetabolites.org/.

Published

2020

8. ARTS 2.0 : feature updates and expansion of the Antibiotic Resistant Target Seeker for comparative genome mining

Author

Mungan, Mehmet Direnç, Alanjary, Mohammad, Blin, Kai, Weber, Tilmann, Medema, Marnix H., Ziemert, Nadine, Mungan, Mehmet Direnç, Alanjary, Mohammad, Blin, Kai, Weber, Tilmann, Medema, Marnix H., and Ziemert, Nadine

Abstract

Multi-drug resistant pathogens have become a major threat to human health and new antibiotics are urgently needed. Most antibiotics are derived from secondary metabolites produced by bacteria. In order to avoid suicide, these bacteria usually encode resistance genes, in some cases within the biosynthetic gene cluster (BGC) of the respective antibiotic compound. Modern genome mining tools enable researchers to computationally detect and predict BGCs that encode the biosynthesis of secondary metabolites. The major challenge now is the prioritization of the most promising BGCs encoding antibiotics with novel modes of action. A recently developed target-directed genome mining approach allows researchers to predict the mode of action of the encoded compound of an uncharacterized BGC based on the presence of resistant target genes. In 2017, we introduced the 'Antibiotic Resistant Target Seeker' (ARTS). ARTS allows for specific and efficient genome mining for antibiotics with interesting and novel targets by rapidly linking housekeeping and known resistance genes to BGC proximity, duplication and horizontal gene transfer (HGT) events. Here, we present ARTS 2.0 available at http://arts.ziemertlab.com. ARTS 2.0 now includes options for automated target directed genome mining in all bacterial taxa as well as metagenomic data. Furthermore, it enables comparison of similar BGCs from different genomes and their putative resistance genes.

Published

2020

9. The antiSMASH database version 2 : a comprehensive resource on secondary metabolite biosynthetic gene clusters

Author

Blin, Kai, Pascal Andreu, Victòria, de Los Santos, Emmanuel L.C., Del Carratore, Francesco, Lee, Sang Yup, Medema, Marnix H., Weber, Tilmann, Blin, Kai, Pascal Andreu, Victòria, de Los Santos, Emmanuel L.C., Del Carratore, Francesco, Lee, Sang Yup, Medema, Marnix H., and Weber, Tilmann

Abstract

Natural products originating from microorganisms are frequently used in antimicrobial and anticancer drugs, pesticides, herbicides or fungicides. In the last years, the increasing availability of microbial genome data has made it possible to access the wealth of biosynthetic clusters responsible for the production of these compounds by genome mining. antiSMASH is one of the most popular tools in this field. The antiSMASH database provides pre-computed antiSMASH results for many publicly available microbial genomes and allows for advanced cross-genome searches. The current version 2 of the antiSMASH database contains annotations for 6200 full bacterial genomes and 18,576 bacterial draft genomes and is available at https://antismash-db.secondarymetabolites.org/.

Published

2019

10. AntiSMASH 4.0 - improvements in chemistry prediction and gene cluster boundary identification

Author

Blin, Kai, Wolf, Thomas, Chevrette, Marc G., Lu, Xiaowen, Schwalen, Christopher J., Kautsar, Satria A., Suarez Duran, Hernando G., De Los Santos, Emmanuel L.C., Kim, Hyun Uk, Nave, Mariana, Dickschat, Jeroen S., Mitchell, Douglas A., Shelest, Ekaterina, Breitling, Rainer, Takano, Eriko, Lee, Sang Yup, Weber, Tilmann, Medema, Marnix H., Blin, Kai, Wolf, Thomas, Chevrette, Marc G., Lu, Xiaowen, Schwalen, Christopher J., Kautsar, Satria A., Suarez Duran, Hernando G., De Los Santos, Emmanuel L.C., Kim, Hyun Uk, Nave, Mariana, Dickschat, Jeroen S., Mitchell, Douglas A., Shelest, Ekaterina, Breitling, Rainer, Takano, Eriko, Lee, Sang Yup, Weber, Tilmann, and Medema, Marnix H.

Abstract

Many antibiotics, chemotherapeutics, crop protection agents and food preservatives originate from molecules produced by bacteria, fungi or plants. In recent years, genome mining methodologies have been widely adopted to identify and characterize the biosynthetic gene clusters encoding the production of such compounds. Since 2011, the â € antibiotics and secondary metabolite analysis shell - antiSMASH' has assisted researchers in efficiently performing this, both as a web server and a standalone tool. Here, we present the thoroughly updated antiSMASH version 4, which adds several novel features, including prediction of gene cluster boundaries using the ClusterFinder method or the newly integrated CASSIS algorithm, improved substrate specificity prediction for non-ribosomal peptide synthetase adenylation domains based on the new SANDPUMA algorithm, improved predictions for terpene and ribosomally synthesized and post-translationally modified peptides cluster products, reporting of sequence similarity to proteins encoded in experimentally characterized gene clusters on a per-protein basis and a domain-level alignment tool for comparative analysis of trans-AT polyketide synthase assembly line architectures. Additionally, several usability features have been updated and improved. Together, these improvements make antiSMASH up-to-date with the latest developments in natural product research and will further facilitate computational genome mining for the discovery of novel bioactive molecules.

Published

2017

11. The antiSMASH database, a comprehensive database of microbial secondary metabolite biosynthetic gene clusters

Author

Blin, Kai, Medema, M.H., Kottmann, Renzo, Lee, Sang Yup, Weber, Tilmann, Blin, Kai, Medema, M.H., Kottmann, Renzo, Lee, Sang Yup, and Weber, Tilmann

Abstract

Secondary metabolites produced by microorganisms are the main source of bioactive compounds that are in use as antimicrobial and anticancer drugs, fungicides, herbicides and pesticides. In the last decade, the increasing availability of microbial genomes has established genome mining as a very important method for the identification of their biosynthetic gene clusters (BGCs). One of the most popular tools for this task is antiSMASH. However, so far, antiSMASH is limited to de novo computing results for user-submitted genomes and only partially connects these with BGCs from other organisms. Therefore, we developed the antiSMASH database, a simple but highly useful new resource to browse antiSMASH-annotated BGCs in the currently 3907 bacterial genomes in the database and perform advanced search queries combining multiple search criteria. antiSMASH-DB is available at http://antismash-db.secondarymetabolites.org/.

Published

2016